EP1655804A2 - Device and method for connecting an electrical transfer member to a contact element - Google Patents

Abstract

The method involves guiding an electrical transmission unit and a contact unit for establishing a connection of an operating station, where the transmission unit consists of an electrical conductor, which is surrounded by a wire sheath. The wire sheath is crimped with a crimp unit of the contact unit in the operating station. The electrical conductor is welded with the contact area of the contact unit, in an operating process. An independent claim is also included for a device for connecting an electrical transmission unit with a contact unit.

Description

The present invention relates to a method and a device for connecting an electrical transmission element to a contact element, wherein the electrical transmission element has at least one electrical conductor, which is surrounded by a wire sheath.

According to a known method for connecting an electrical transmission element, for example in the form of an electrical cable, with a contact element, an exposed electrical conductor of the transmission element on the one hand and a conductor sleeve of the transmission element, for example in the form of electrical insulation, on the other hand each connected to the contact element by be crimped by means of a separate crimping of the contact element. In such a crimping process, on the one hand, a conductor crimping region of the contact element is brought into pressing or crimping contact with the electrical conductor of the transmission element and, on the other hand, the core sheath, for example in the form of insulation, of the electrical transmission element is brought into press or crimp contact with an insulation crimping region of the contact element. to attach the transmission element to the contact element.

DE 103 58 153 A1 describes a connection method and a connection arrangement of an electrical cable with a contact element. According to the connection method for connecting the electric wire to a contact member, after a conductor of the electric wire is crimped, it is connected to a conductor crimping portion of the contact member, the conductor and the conductor crimping portion are welded by passing a laser beam on a bottom wall of the conductor crimping portion. For this purpose, the electrical cable first has to be fed to a conductor crimping area, which first crimps the conductor of the electrical cable to the conductor crimping section of the contact element and the cable sheath of the cable to the insulation crimping area. Thereafter, the electrical cable and contact member connection assembly thus produced is fed to a laser welding apparatus which directs the laser beam to a bottom wall of the cable crimping portion to make the welded joint. In such an approach, the electrical cable and the contact member for performing the crimping operation are first supplied to the crimping apparatus, then the prepared connection assembly must be removed from the crimping apparatus before being supplied to the laser welding apparatus to perform the welding operation in a separate operation. Such a connection method in several separate operations requires a relatively large amount of time in the implementation of the connection method and requires several processing stations with a correspondingly high equipment costs.

The present invention has for its object to provide a method and apparatus for connecting an electrical transmission element with a contact element, which is or is suitable to keep the time required and the equipment costs for performing the connection method comparatively low.

The object concerning the method is achieved by a method for connecting an electrical transmission element to a contact element according to claim 1. The object concerning the device is achieved by a device for connecting an electrical transmission element with a contact element according to claim 11.

According to the inventive method for connecting an electrical transmission element with a contact element, the electrical transmission element and the contact element for making a connection to a workstation are supplied and remain for a work with a certain residence time in the workstation before they are removed from the workstation again. In the workstation, the core sheath of the electrical transmission element, which surrounds an electrical conductor, is crimped with at least one crimping element of the contact element. During the same dwell time of the contact element in the workstation or during the same work cycle of the workstation, the electrical conductor of the transmission element is welded to a contact region of the contact element. Thus, according to the method of the invention, the crimping operation and the welding operation for establishing the connection between the electrical transmission element and the contact element are carried out within a common workstation within a common workstation, so that a common workstation is used for both operations in a common operation belonging to the same work cycle or same residence time can be. This makes it possible to achieve a significant reduction in a cycle time for the production of a connection between a transmission element and a contact element, since the transport process of the connection arrangement formed from a crimping device into a separate welding device can be dispensed with according to the invention.

The device according to the invention for connecting an electrical transmission element to a contact element contains a feed device for feeding a contact element and a electrical transmission element and a work station, which are supplied to the contact element and the electrical transmission element by the feed device. The workstation is designed in such a way that the elements to be connected remain in the workstation for a certain length of time before they are removed again from the workstation. The workstation includes a crimping device that is configured and operable to crimp the wire sheath of the electrical transmission element with at least one crimping element of the contact element. Furthermore, the workstation includes a welding device that is configured and operable to weld the electrical conductor to a contact region of the contact element. The crimping device and the welding device are adapted to be operated in a common operation for a crimping operation and a welding operation belonging to the same working cycle or the same residence time.

For the application that the electrical transmission element comprises a plurality of electrical conductors, in particular a Litzendrahtanordnung, which are surrounded by a common core sheath, at least a portion of the electrical conductors is welded to a contact region of the contact element in the workstation. At least several of the electrical conductors are compacted with each other, i. the individual wires of the strand bundle are welded together to form a bundle. Preferably, in the compacting welding process, the compacted strand bundle is also welded to the contact element.

According to one embodiment of the invention, the electrical conductor is welded to the contact region of the contact element while the insulation crimping tool is in the crimping position. For this purpose, in particular a crimping device is closed, so that the core of the electrical transmission element is crimped with the crimping of the contact element. During the same working stroke or residence time of the contact element in the work station, the electrical conductor is welded to the contact region of the contact element, for example by means of a resistance welding process in which a first welding electrode and a second welding electrode contact the elements to be welded from opposite sides. During the welding process, the transfer element is held by the crimping device. After completion of the welding process, the crimping device is released again, so that the connection arrangement thus formed is released.

In a further embodiment of the invention, the electrical conductor is held by a support means of the workstation against an evasion tendency during the welding operation. For example, the support device has laterally to the elements to be welded paired support elements, wherein a first of the support elements on a first side and a second of the support elements on an opposite second side of the elements to be welded are arranged. The support elements are designed for example as ceramic jaws, which are placed on both sides next to the elements to be welded in position. In a support position, the support elements are preferably arranged such that they rest without lateral spacing on the respective side of the elements to be welded.

In order to approximate the support means to the elements to be welded, the support means is preferably movable along a second axis which is approximately orthogonal to a first axis along which the welding device is moved to approach the elements to be welded, by energizing to carry out the welding process. For example, the welding device is movable along a vertical axis, whereas the individual support elements of the support means are approximated along a horizontal axis laterally to the elements to be welded.

In particular, in the case where a plurality of contact elements are lined up and intermittently fed to the workstation, the support means is further movable along a third axis which is approximately orthogonal to said two other axes. According to one embodiment of the connection method, the support device is moved along the third axis before the welding operation in order to bring the support device between the lined-up contact elements. Subsequently, the support means is laterally approximated along the second axis of the elements to be welded in order to take the support position.

Alternatively or in addition to the movement along the third axis, the support device can be moved in a direction running at least approximately parallel to the first axis before the support elements are moved along the second axis to the elements to be welded.

In one embodiment of the invention, the two lateral support elements of the support means are locked via a clip or a clasp-like locking element for receiving the lateral forces arising during the welding process.

According to a further embodiment of the invention, a separating device is included in the workstation to separate the contact element to be welded from a carrier element to which a plurality of processing contact elements are attached. For example, a plurality of contact elements in a row are connected on one side with a carrier strip, which is separated in the workstation from the contact element to be connected. Preferably, the separating device is brought to the same displacement in a detaching position in which the crimping is brought into crimping position to crimp the wire sheath with the crimping element of the contact element. This can in turn achieve a significant time savings during the connection process, since the removal process is carried out simultaneously with the crimping process to be carried out anyway.

In a further development of the invention, the separating device has a knife and a movable plunger, which acts in an impact direction on the knife and moves it in the impact direction in order to separate the carrier element from the contact element. Preferably, the plunger is connected to the crimping device, so that the plunger and the crimping device are moved in synchronism with each other in a traversing operation for approaching the knife or to the contact element.

In one embodiment of the invention, the workstation according to the invention can be arranged in a module rack and formed therein as an exchangeable change tool. This makes it possible to make an adaptation to various types of contact elements and / or various types of electrical transmission elements of a production line. If, for example, after a series of several supplied contact elements of a first type of workstation, a further series of different contact elements supplied thereto, it is possible with the inventive device, the workstation for processing the first series of contact elements against a workstation for processing the second Replacing a series of contact elements with a short disassembly or assembly time.

For this purpose, the workstation is, for example, on a support plate, which is mounted by means of a quick-release device on the module frame and can be removed from this. In this way it is possible to disassemble a first workstation quickly and replace it with a second workstation.

With the method according to the invention and the device according to the invention, it is fundamentally possible to connect different types of electrical transmission elements with different types of contact elements. For example, the electrical transmission element is designed as an electrical cable, in which an electrical conductor is surrounded by a cable sheath as a core sheath. Furthermore, the electrical transmission element may be formed as a single electrical wire within a bundle of a plurality of electrical transmission elements, wherein the bundle is surrounded by a common cable sheath. In the latter case, the electrical conductor of a transmission element is surrounded only by insulation as a buffer tube. The electrical conductor, in turn, in one embodiment, as already described above, can be embodied as a unitary wire or as a stranded wire arrangement with a plurality of stranded, electrically conductive wires.

Further advantageous embodiments and further developments of the invention are specified in subclaims.

Figur 1

eine Ausführungsform einer erfindungsgemäßen Vorrichtung zur Verbindung eines elektrischen Übertragungselements mit einem Kontaktelement mit einer Arbeitsstation in einer dreidimensionalen Ansicht,

Figur 2

eine Detaildarstellung einzelner Elemente der Ausführungsform der erfindungsgemäßen Vorrichtung in einer Seitenansicht,

Figur 3

eine weitere Detaildarstellung einzelner Elemente der Ausführungsform der erfindungsgemäßen Vorrichtung in einer dreidimensionalen Ansicht,

Figur 4

eine Darstellung einzelner Elemente der Ausführungsform der erfindungsgemäßen Vorrichtung in einer dreidimensionalen Ansicht,

Figur 5

eine Darstellung einzelner Elemente der Ausführungsform der erfindungsgemäßen Vorrichtung in einer Frontalansicht,

Figur 6

eine weitere Detailansicht von Elementen der Ausführungsform der erfindungsgemäßen Vorrichtung in einer dreidimensionalen Darstellung,

Figur 7

eine weitere Detailansicht von Elementen der Ausführungsform der erfindungsgemäßen Vorrichtung in einer dreidimensionalen Darstellung,

Figur 8

eine Detailansicht einer Kühlvorrichtung der Ausführungsform der erfindungsgemäßen Vorrichtung,

Figur 9

eine Ausführungsform einer erfindungsgemäßen Vorrichtung mit einer Arbeitsstation, die in einem Modulgestell angeordnet ist.

The invention will be explained in more detail below with reference to the figures shown in the drawing, which illustrate embodiments of a connecting device according to the invention. Show it

FIG. 1

An embodiment of a device according to the invention for connecting an electrical transmission element with a contact element with a workstation in a three-dimensional view,

FIG. 2

a detailed representation of individual elements of the embodiment of the device according to the invention in a side view,

FIG. 3

a further detailed representation of individual elements of the embodiment of the device according to the invention in a three-dimensional view,

FIG. 4

a representation of individual elements of the embodiment of the device according to the invention in a three-dimensional view,

FIG. 5

an illustration of individual elements of the embodiment of the device according to the invention in a front view,

FIG. 6

a further detail view of elements of the embodiment of the device according to the invention in a three-dimensional representation,

FIG. 7

a further detail view of elements of the embodiment of the device according to the invention in a three-dimensional representation,

FIG. 8

a detailed view of a cooling device of the embodiment of the device according to the invention,

FIG. 9

an embodiment of a device according to the invention with a workstation which is arranged in a module frame.

The structure of an embodiment of a device according to the invention for connecting an electrical transmission element to a contact element will be explained in more detail below with reference to FIGS. 1 to 3.

Figure 1 shows in a three-dimensional view of an embodiment of a workstation 2, the plurality of contact elements 5, which are connected on one side with a carrier strip 53, fed via a feed device to be connected to an electrical transmission element 6 respectively. Figures 2 and 3 show respective detailed representations of the workstation 2 according to Figure 1. As shown in more detail with reference to Figure 2, the workstation 2 is supplied by the feeder, an electrical transmission element 6, which has an electrical conductor 61 within a wire sheath 62. The wire sheath 62 is designed, for example, as insulation, the electrical conductor 61 comprises, for example, a stranded wire arrangement in which several individual electrically conductive strands are stranded to form an electrical conductor. The transfer element 6 with the exposed conductor 61 is placed on a surface of a support knife 30, above a contact element 5, with which it is to be connected. The contact element 5 has in the present embodiment, two crimping elements in the form of Crimplaschen 51, as shown in more detail in particular with reference to FIG 3. These Crimplaschen 51 serve to the wire sheath 62 of the transmission element 6 with the contact element 5 are crimped by the crimping tabs 51 with the core sheath 62, so that a pressing or crushing contact between the Crimplaschen 51 and the core sheath 62 is made. In this context, it is also possible in principle to provide as crimping element only one crimping plate, which is brought into crimping contact with the core sheath.

The contact elements 5, which are fixed to the carrier strip 53, from left to right by means of a guide rail 72 which is arranged on a feed plate 73 and forms a feed gap between itself and the feed plate 73, the subsequent processing operation for connection to the electrical transmission element. 6 fed. The carrier strip 53 has for this purpose transport openings 54 (see for example Figure 5), in which a feed finger 70 engages to move the carrier strip 53 with an intermittent movement from left to right. The feed finger 70 is guided for this purpose along the guide rail 72 (Figure 5) which is mounted on the feed plate 73. To move the feed finger 70 is a pneumatic feed 74, which moves intermittently from left to right and engages with a return movement in a new transport opening 54 by means of the feed finger 70.

The workstation 2 has a crimping device comprising a plurality of components. A crimping tool 10 is used to bring the Crimplaschen 51 of the contact element 5 in crimping contact with the buffer tube 62 of the transmission element 6. For this purpose, the crimping tool 10 is moved vertically downwards in a travel path, with the crimping lugs 51 being bent inwards on the basis of the predetermined profile of the lower end of the crimping tool 10 in order to produce the crimping contact. For the movement of the crimping tool 10 is a lifting cylinder 13, with which a fastening plate 11 for the crimping tool 10 is moved so that the crimping tool 10 is moved downwards with the fastening plate 11 for a crimping operation. The crimping tool 10 is connected via a crimp height adjustment 12 with the mounting plate 11, which serves to adjust the crimping tool in the final position in its height exactly, so that an adaptation to different diameters of transmission elements is possible. The crimp height adjustment 12 is in the form of an eccentric, which is rotated accordingly to adjust the crimping tool 10 to the desired height. When the crimping lugs 51 are pressed down by the crimping tool 10, a counterforce is built up by the anvil 14, which supports the electrical contact element 5 against the crimping tool 10 at the position of the crimping lugs 51.

The workstation 2 further includes a welding device configured as a welding device for performing a resistance welding process. It has an upper welding electrode 22 and a lower welding electrode 23, which are supplied with an electrical supply voltage to generate a welding current. The contact element 5 is arranged with the contact region 52 between the electrodes 22 and 23. The upper electrode 22 is held by the electrode holder 21, which is tuned to the particular welding electrode used and in turn is attached to a clamp 20 for the electrode holder (Figure 9). As further illustrated by FIG. 9, the electrode holder 21 is connected to a welding head arrangement 4 via the clamp 20. This welding head assembly 4 serves to vertically position the upper welding electrode 22. The welding current is generated externally and supplied to the welding electrodes 22 and 23 via connecting lines (not shown in the figures). According to Figure 2, the anvil 14 for the crimping tool 10 by an insulation 15 against the lower electrode 23 isolated. In addition to the lower electrode 23 is a contact support 24, preferably made of electrically non-conductive material, provided to support the contact element 5 during the welding operation downwards.

The upper electrode 22 with the electrode holder 21 can be approached along a first axis 81 to the elements to be welded in the form of the electrical conductor 61 and the contact region 52. The axis 81 is in the present embodiment in a vertical arrangement. If the upper electrode 22 is brought to the elements to be welded 61 and 52, the electrodes 22 and 23 are acted upon by an electrical supply voltage, so that a welding current flows through the components 52 and 61 to be welded. These form an electrical resistance to the welding current, so that the elements to be welded become very hot, thus causing welding, i. an intimate connection between the electrical conductor 61 and the contact region 52 of the electrical contact element 5 is brought about. When the electrical conductor 61 is a stranded wire assembly of a plurality of stranded strands of wire, at least a portion of these strands of wire are welded to the contact portion 52 and at least a portion of the strands of wire are compacted together, i. the individual wires of the strand bundle are welded together to form a bundle. As a result, an intimate connection between the wire strands is produced, so that a good overall contact between the stranded wire arrangement and the contact element is produced.

In contrast to the connection method according to DE 103 58 153 A1, no crimping of the electrical conductor 61 or of the stranded wire arrangement 61 is performed with a conductor crimping region of the contact element 5. This makes it possible, the entire contact area 52 via to use its entire length for an intimate weld with the electrical conductors or the.

According to the invention, therefore, the welding device and crimping device for the connection of the electrical transmission element to the contact element are contained in a common workstation 2, to which the contact element 5 and the electrical transmission element 6 are fed intermittently. These remain in the workstation 2 for an operation with a certain residence time before they are removed again as a connection arrangement of the workstation. The crimping and the welding operation are carried out in the common workstation 2 in one operation, so that a transport operation is omitted by a crimping tool in a separate welding tool. Thereby, the total time (cycle time) for the common insulation crimping and conductor wire welding per contact element can be considerably reduced to about 1000 to 1500 ms.

The further construction of an embodiment of the connecting device according to the invention will be explained in more detail with reference to the illustrations of FIGS. 4 to 7.

In the workstation 2, in addition to the already described components, a support device 40 is furthermore provided, which serves to support the elements 52 and 61 to be welded during the welding operation against forces exerted by the welding operation on the elements to be welded and a tendency to evasion of the weld metal to the side cause. The support means 40 has laterally to the elements to be welded 52 and 61 paired support members 41 in the form of ceramic jaws, wherein a first ceramic jaw 41 on one side and a second ceramic jaw 41 on an opposite side of the elements to be welded 52 and 61 are arranged. The use of ceramic is advantageous in this context because it is an insulating material that prevents the welding current from flowing through the support.

To approach the elements to be welded 52 and 61, the ceramic jaws 41 along the second axis 82 are movable, which is arranged approximately orthogonal to the first axis 81. This means in the present embodiment that the ceramic jaws 41 are approximated along a horizontal axis laterally to the elements 52 and 61 to be welded.

The ceramic jaws 41 are guided by holders 42, which in turn are attached to parallel grippers 43. A feed cylinder 45 is used for movement, more precisely for the forward and reverse thrust of the parallel gripper 43. Via a cylinder 46, a locking bracket 44 is movable, which is provided as a bow-shaped or clasp-like locking element to the paired ceramic jaws 41 in its supporting position against To support in the direction of support laterally acting forces that arise as a result of the welding process. This makes it possible to make the ceramic jaws 41 filigree, so that they can be easily moved between the contact elements 5, which are still attached to the carrier strip 53.

Before a welding operation, the support device 40 is moved with the ceramic jaws 41, the holders 42 and the parallel grippers 43 along a third axis 83 in the direction of the carrier strip 53, the third axis 83 approximately orthogonal to the first axis 81 and to the second axis 82 is arranged. The parallel gripper 43 become moved by the feed cylinder 45 for this purpose. Thereby, the ceramic jaws 41 are brought into a lateral position to the elements to be welded 52 and 61, so that they can then be brought along the second axis 82 to the elements to be welded.

As can be seen more clearly in particular with reference to FIGS. 1 to 3, the workstation 2 furthermore contains a separating device which serves to separate the contact element 5 to be welded from the carrier strip 53, to which a plurality of contact elements 5 to be processed are arranged next to one another. The separating device has a serving both as a separating knife and as a cable carrier support blade 30 and a plunger 31 which is moved for a separation process down. In this thrust direction of the movable plunger 31 acts on the support blade 30, on the raised, left-hand projection of the support blade 30, so that the support blade 30 is pressed at this point by the plunger 31 down. Thus, the support blade 30 is moved in the direction of impact of the plunger 31 down, so that the carrier strip 53 is separated by the support blade 30 from the contact element 5.

According to the present embodiment, the plunger 31 is connected via a fastening screw 32 with the crimping tool 10. In this way, the plunger 31 and the crimping tool 10 are moved synchronously with one another in a movement process for approaching the support blade 30 or for approaching the contact element 5.

The sequence of a connection process for connecting an electrical transmission element 6 to a contact element 5 will be described below in more detail.

The individual contact elements 5 are conveyed by the feed mechanism described intermittently to the workstation 2, wherein the respective contact element 5 to be connected in the welding / crimping of the described workstation 2, where it is supported by the contact support 24. The transmission element 6 is approximated from the front (Figure 1) or from the left (Figure 2) to the contact element 5 and comes to lie on the right surface portion of the support blade 30. Subsequently, the crimping tool 10 is closed, in which it is lowered onto the anvil 14. By this operation, the Crimplaschen 51 are pressed to a crimping contact on the buffer tube 62 and synchronously, the contact element 5 is separated from the carrier strip 53 by means of the support blade 30, which is pressed by the plunger 31 down.

Subsequently, the ceramic jaws 41 are brought along the axis 83 on both sides next to the contact element 5 in position and closed along the axis 82 to abut without lateral spacing on the respective side of the contact element 5. For this purpose, the holders 42 are advanced for the ceramic jaws 41 from back to front by the parallel gripper 43 are moved by means of the feed cylinder 45 to the front. Here, the holder 42 for the ceramic jaws 41 are still in the open state until they are located on both sides of the respective positioned contact element 5. Then, the ceramic jaws 41 are moved along the axis 82 sideways on the two longitudinal sides of the contact element 5 until they rest thereon. Before the welding process, the locking bracket 44 is slipped over the ceramic jaw holder 42 in the closed position in order to prevent lateral deflection of the ceramic jaws 41 as a result of the welding forces. This is during the welding process Crimping tool 10 in the closed state to hold the transmission element 6 in position.

For the welding operation, the upper welding electrode 22 is moved down to the fixed lower welding electrode 23. During the welding process, the strands of the stranded wire assembly 61 are laterally supported by the ceramic jaws 41. After the welding process, the ceramic jaws 41 are opened along the axis 82 and the crimping tool 10 and the upper welding electrode 22 are moved upwards along the axis 81 so that the transmission element 6 can be removed from the work station 2 with the contact element 5 welded thereto and crimped on.

In order not to let the individual components of the workstation 2 to heat too much during the welding process, a cooling device 75 is provided according to Figure 8, which includes a plurality of tubes in which, for example, cooling medium can be performed in the form of a cooling fluid, for example in the form of cooling air or cooling water. For example, assuming an embodiment with cooling water as the cooling medium, the cooling water is introduced, for example, at the cooling water inlet 76 into the cooling device 75 and removed again at the cooling water outlet 77 of the cooling device 75. This causes the support plate 71, on which the workstation 2 is arranged, not to overheat and thus deform as a result of the welding operation.

FIG. 9 shows an embodiment of a device 1 according to the invention with a work station 2, as described in greater detail with reference to FIGS. 1 to 8, in a module frame. The workstation 2 (so-called applicator) is arranged on a carrier plate 71 (see, for example, FIG. 1), which is provided by means of a quick-action clamping device (not shown) can be mounted on a module frame 3 and disassembled from this. Thus, the workstation 2 is arranged in the module frame 3 as an exchangeable change tool and disassembled from this with little effort. This can be done to adapt to various types of contact elements and transmission elements. The welding head assembly 4 with servomotor welding head with welding parameter monitoring remains firmly connected to the module frame 3. The module frame 3 is in turn mounted on a corresponding manufacturing device. In the replacement of the workstation 2, the welding electrodes 22 and 23 are changed in accordance with this embodiment, so that a suitable interface to the module frame 3 and the welding head assembly 4 must be provided, with which the welding electrodes can be coupled to a power supply.

Claims (26)

Method for connecting an electrical transmission element (6) to a contact element (5), wherein the electrical transmission element (6) has at least one electrical conductor (61) surrounded by a buffer tube (62), - In which the electrical transmission element (6) and the contact element (5) for making a connection to a workstation (2) are supplied and remain for a work with a certain residence time in the workstation (2) before they are removed from the workstation again, - In which in the workstation (2) the core sheath (62) with at least one crimping element (51) of the contact element (5) is crimped and welded in the same operation of the electrical conductor (61) with a contact region (52) of the contact element (5) becomes. Method according to Claim 1, in which the electrical transmission element (6) has a plurality of electrical conductors (61), in particular a stranded wire arrangement, which are surrounded by a common core sheath (62), wherein at least a part of the electrical conductors (2) in the workstation (2). 61) is welded to a contact region (52) of the contact element (5) and at least a plurality of the electrical conductors (61) are compacted with each other. Method according to Claim 1 or 2, in which the electrical connection between the at least one electrical conductor (61) and the contact element (5) takes place without crimping. Method according to one of the preceding claims, in which the electrical conductor (61) is welded to the contact region (52) of the contact element (5) while the wire sheath (62) is crimped by means of a crimping device (10) for crimping the core sheath (62) with an insulation crimping region (51) of the contact element (5) is held. Method according to one of the preceding claims, in which the electrical conductor (s) (61) are held by a supporting device (40) of the workstation (2) against an evasion tendency during the welding operation. The method of claim 5, wherein the welding takes place by means of an energy supply along a first axis 81, - The one or more electrical conductors (61) by a along a second axis (82) movable support means (41, 42, 43) are held, wherein the second axis (82) to the first axis (81) is arranged approximately orthogonal. The method of claim 6, wherein before the welding operation, the support means (41, 42, 43) is moved along a third axis (83) towards the respective contact element (5), the third axis (83) being approximately orthogonal to the first and third second axis (81, 82) is arranged, and then along the second axis (82) is moved to take the support position. The method of claim 6 or 7, wherein the support means (41, 42, 43) is moved approximately parallel to the first axis (81) towards the respective contact element (5) and then along the second axis (82) before welding to take the support position. Method according to one of the preceding claims, in which - The contact element (5) is connected to the supply to the workstation (2) with a carrier element (53), - In the workstation (2), the contact element (5) from the carrier element (53) is separated. The method of claim 9, wherein - The core sheath (62) is crimped with at least one crimping element (51) of the contact element (5) by a crimping device (10) is brought into a crimping position in a movement, - The contact element (5) from the carrier element (53) by a separating device (30, 31) is separated, which is brought into the removal position with the same traversing operation. Method according to one of the preceding claims, in which a resistance welding method is used for the welding. Device for connecting an electrical transmission element to a contact element, - With a contact element supply means (70, 72, 73, 74) for supplying a contact element (5), - With a workstation (2), on the one hand, the electrical transmission element (6) and on the other hand by means of the feeder (70, 72, 73, 74), the contact element (5) are supplied, which for a work with a certain residence time in the workstation (2) remain before they are removed from the workstation, where - the work station (2) comprises a crimping device (10) which is designed and operable to crimp the wire sheath (62) of the electrical transmission element (6) with at least one insulation crimping region (51) of the contact element (5), the workstation (2) comprises a welding device (22, 23) adapted and operable to weld the electrical conductor (61) to a contact region (52) of the contact element (5), - And the crimping device (10) and the welding device (22, 23) are adapted to be operated in one operation for a crimping and a welding operation. Apparatus according to claim 11, wherein a transfer member feeding means (30) is provided, wherein - An electrical transmission element (6) with a plurality of electrical conductors (61), in particular with a Litzendrahtanordnung, can be supplied by the transmission element feed device (30), which are surrounded by a common core sheath (62), - The welding device (22, 23) is adapted and operable to at least a part of the electrical conductors (61) with a contact region (52) of the contact element (5) to weld and at least more of the electrical conductors (61) to compact one another. Apparatus according to claim 12 or 13, which is designed and operable to produce a crimp-free electrical connection between the at least one electrical conductor (61) and the contact element (5). Apparatus according to any one of claims 12 to 14, wherein the work station (2) comprises support means (40) adapted and operable such that the elements (52,61) to be welded during welding against evasive tendencies exert forces from the Supporting device (40) are held. Apparatus according to claim 15, wherein the support means (40) has paired support members (41) laterally of the members (52, 61) to be welded, a first of the support members (41) on a first side and a second of the support members (41 ) on an opposite second side of the elements to be welded (52, 61) can be arranged. Apparatus according to claim 16, wherein a locking element (44) is provided, which supports the pairs of support elements (41) in the supporting position counteracting in the direction of support forces. Device according to one of claims 15 to 17, in which - The welding device (22, 23) along a first axis (81) to the electrical transmission element (6) and the contact element (5) is approachable to perform by a power supply, the welding operation, - The support means (40) for approaching the elements to be welded (52, 61) along a second axis (82) is movable, which is arranged approximately orthogonal to the first axis (81). The apparatus of claim 18, wherein the support means (40) is movable along a third axis (83) disposed approximately orthogonal to the first and second axes (81, 82) to move the support means (40) to a lateral position to bring the elements to be welded (52, 61). Apparatus according to claim 18 or 19, wherein before the welding operation, the support means (41, 42, 43) is movable approximately parallel to the first axis (81) towards the respective contact element (5) to move the support means (40) to a lateral position to bring to the elements to be welded (52, 61). Device according to one of claims 12 to 20, wherein the work station (2) has a separating device (30, 31) for separating the contact element (5) to be welded from a carrier element (53) on which a plurality of contact elements (5 ) are mounted. Apparatus according to claim 21, wherein the severing means comprises a knife (30) and a movable plunger (31) acting in a thrust direction on the knife (30) and moving it in the impact direction to move the support member (53) away from the contact element (30). 5). Apparatus according to claim 22, wherein the plunger (31) is connected to the crimping means (10) so that the plunger (31) and the crimping means (10) in a traversing operation for approaching the knife (30) or to the contact element (5) are moved synchronously to each other. Device according to one of claims 12 to 23, wherein the welding device (22, 23) is adapted to perform a resistance welding process. Device according to one of claims 12 to 24, wherein the workstation (2) in a module frame (3) can be arranged and is formed therein as an exchangeable change tool. Device according to Claim 25, in which the work station (2) is arranged on a carrier plate (71) which can be mounted on and dismounted from the module frame (3) by means of a quick-action clamping device.

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