阅读说明：本技术 用于对绞合导线与接触件之间的材料锁合的接合连接进行检查的方法和系统 (Method and system for testing a bonded connection between a stranded conductor and a contact element ) 是由 丹尼尔·泽曼 斯特凡·尤因 卢茨·莱曼 于 2020-02-11 设计创作，主要内容包括：本发明涉及一种用于对绞合导线(12)与接触件(14)之间的材料锁合的接合连接(10)进行检查的方法,该方法包括以下步骤：借助于固定装置(24)来固定所述绞合导线(12)的具有多根材料锁合地彼此连接的单线的焊接节点(20)；借助于至少间接地作用在所述接触件(14)上的检查装置(28)通过所述接触件(14)从所述绞合导线(12)上的脱落来破坏所述接合连接(10)。此外,本发明涉及一种用于对绞合导线(12)与接触件(14)之间的材料锁合的接合连接(10)进行检查的系统(22)。(The invention relates to a method for testing a bonded joint (10) between a stranded conductor (12) and a contact element (14), comprising the following steps: fixing a welded joint (20) of the stranded conductor (12) having a plurality of individual wires which are connected to one another in a material-locking manner by means of a fixing device (24); the bonded connection (10) is broken by the contact (14) falling off the stranded conductor (12) by means of an inspection device (28) acting at least indirectly on the contact (14). The invention further relates to a system (22) for testing a bonded joint connection (10) between a stranded conductor (12) and a contact element (14).)

1. Method for checking a bonded joint (10) between a stranded conductor (12) and a contact element (14), comprising the following steps:

-fixing a welded joint (20) of the stranded conductor (12) with a plurality of individual wires connected to one another in a material-locking manner by means of a fixing device (24);

-breaking the bonded connection (10) by the contact (14) falling off the stranded conductor (12) by means of an inspection device (28) acting at least indirectly on the contact (14).

2. The method of claim 1, wherein the first and second light sources are selected from the group consisting of,

it is characterized in that the preparation method is characterized in that,

the force (F) exerted to the greatest extent by means of the inspection device (28) for the purpose of detaching the contact piece (14) is ascertained and the quality of the cohesive connection is evaluated on the basis thereof.

3. The method according to claim 1 or 2,

it is characterized in that the preparation method is characterized in that,

before the contact piece (14) is detached, a plug region (16) arranged or molded on the contact piece (14) is removed and the inspection device (28) then acts directly on the contact piece (14) in order to detach the contact piece (14) from the stranded conductor (12).

4. The method according to any one of the preceding claims,

it is characterized in that the preparation method is characterized in that,

the fixing device (24) has two clamping blocks (26), the welding joint (20) being clamped and thereby fixed between the clamping blocks (26).

5. The method according to any one of the preceding claims,

it is characterized in that the preparation method is characterized in that,

the inspection device (28) has two clamping blocks (30), the contact piece (14) being clamped at least indirectly between the clamping blocks (30) and being subjected to a tensile force (F) at least substantially transversely to the longitudinal direction of the conductor strand (12) in order to release the contact piece (14).

6. The method of claim 5, wherein the first and second light sources are selected from the group consisting of,

it is characterized in that the preparation method is characterized in that,

the free end region of the contact piece (14) is first bent out transversely to the longitudinal direction of the stranded conductor (12) and is then subjected to a tensile force (F).

7. The method of claim 5, wherein the first and second light sources are selected from the group consisting of,

it is characterized in that the preparation method is characterized in that,

a tensile force (F) is applied to the free end region of the contact piece (14) and thereby bends it out transversely to the longitudinal direction of the stranded conductor (12).

8. The method of any one of claims 1 to 4,

it is characterized in that the preparation method is characterized in that,

the inspection device (28) has a roller (34), the contact element (14) is at least indirectly fixed to an outer circumferential surface (38) of the roller (34), and the contact element (14) is detached from the stranded conductor (12) by rotation of the roller (34).

9. The method according to any one of the preceding claims,

it is characterized in that the preparation method is characterized in that,

during the stripping of the contact (14), the fixing device (24) is moved relative to the inspection device (28) in such a way that the relative position of a stripping line moving in the longitudinal direction of the conductor strand (12), at which the contact (14) is released from the conductor strand (12), remains at least substantially unchanged relative to the inspection device (28).

10. The method of claim 9, wherein the first and second light sources are selected from the group consisting of,

it is characterized in that the preparation method is characterized in that,

the fixing device (24) is supported in a translatory manner and is tracked in accordance with the moving detachment line for maintaining the relative position of the moving detachment line at least substantially unchanged relative to the inspection device (28).

11. System (22) for checking a bonded joint connection (10) between a stranded conductor (12) and a contact element (14), comprising:

-a fixing device (24) for fixing a welded joint (20) of the stranded conductor (12) having a plurality of individual wires connected to one another in a cohesive manner; and

-an inspection device (28) designed to act at least indirectly on the contact element (14) and to detach the contact element (14) from the stranded conductor (12) in order to break the bonded connection (10).

Technical Field

The invention relates to a method and a system for testing a bonded connection between a stranded conductor and a contact element.

Background

The quality of a bonded joint, in particular an ultrasonically welded, laser welded or resistance-brazed joint, is often not determined without damage during production. It is therefore common to check the quality of an adhesively bonded joint connection in a sampling manner by the maximum breaking force required for separating the joints.

In the automotive industry, this involves, firstly, the ultrasonic welding of the stranded conductors to the contact elements or to one another. Such joints are typically separated during a fracture test by: the contact piece is clamped and pulled on a cable of stranded conductors with a linear pulling device or, in the case of a plurality of stranded conductors, pulled out of a so-called joint or broken.

However, there are situations in which it is not possible to clamp the contact securely. This may be the case in particular if the plate thickness of the contact piece is comparatively small and its width is only slightly greater than the width of a so-called weld joint of the conductor strands, which is a strand of the relevant conductor strand that is connected to one another in a material-locking manner. Such connections cannot be checked in the manner described above.

Disclosure of Invention

The object of the present invention is to provide a solution by means of which an interlocking bond connection between a stranded conductor and a contact piece can be checked and verified particularly for a specific bond connection.

This object is achieved by a method and a system for testing a bonded joint connection between a stranded conductor and a contact element, which method and system have the features of the independent claims. Advantageous embodiments of the invention are specified in the dependent claims together with suitable and important refinements.

In the method according to the invention for testing a cohesive connection between a conductor strand and a contact element, a welded joint of the conductor strand having a plurality of individual wires joined to one another in a cohesive manner is fixed at least indirectly by means of a fixing device. In order to check the cohesive bond connection, the bond connection is then broken by the contact falling off the conductor strand and, more precisely, by means of a checking device acting at least indirectly on the contact.

The fixing device can be, for example, a clamping device, by means of which the welded joint is clamped, for example, in that the plates of the contact piece are subsequently separated. In the case of a typical connection of a strand to a contact element, instead of clamping the contact element and peeling the strand as in the past, in other words, the solder joints of the strand are clamped and the contact element is separated, for example, by peeling. The strand is thus deformed during the conventional test described at the outset, while for the purposes of the present invention the contact is detached from the strand in the event of a destruction of the bond connection for testing the cohesive bond connection between the strand and the contact.

The advantage of the method according to the invention is, in particular, that no inspection of the cohesive connection is necessary in the design of the welding geometry. In contrast to the conventional inspection method described at the outset, the deformation of the contact is favorable and necessary for the disconnection of the connection. In the case of thin plates, the contact elements can be undesirably deformed in conventional inspection methods, which leads to a high degree of dispersion of the inspection results. For contacts whose width is only slightly greater than the width of the solder joint, only newly developed inspection methods can be employed. In the new inspection method, the contact piece must also be clamped only at other locations for force transmission. The problem described at the outset, for which a fixed clamping of the contact piece is not possible, is thereby directly solved, in particular if the plate thickness of the contact piece is small and its width is only slightly greater than the width of the solder joint.

A further disadvantage of the conventional test described at the outset is that the actual strength of the cohesive joining connection cannot be determined or ascertained from the measured breaking force. A cohesive connection which is checked by means of conventional checking may in fact have a lower strength than other regions, for example in the joining zone, although this is not necessarily indicated by conventional methods.

The reason for this is, in particular, that additional statistical discrepancies are produced by conventional testing processes, since the load situation during testing includes bending of the litz wire or stranded conductor. By bending the litz wire and the welded joint (during the separation process), the individual wires are released from one another — similar to delamination — and thus lead to a greater dispersion. The random variation of the layer of the individual wires has the result that the actual load situation is always different in an uncontrolled manner. The load situation during the examination is more pronounced for the method according to the invention than in the conventional examination described at the outset. The quality of the individual welded or bonded connections is thereby better reflected. By means of the method according to the invention, the maximum breaking force can be used as a quality criterion. The strength of the connection is not ascertained here, since an inhomogeneous stress state exists during the peeling test. However, the so-called peeling resistance can be ascertained by: the maximum breaking force is divided by the width of the break zone.

One possible embodiment of the invention provides for the force applied to the maximum extent by means of the inspection device for the purpose of detaching the contact piece to be ascertained and on the basis thereof the quality of the cohesive connection to be evaluated. In this way, when inspecting the cohesive joining connection, it is very easy to ascertain the quality of the joining connection inspected by breaking on the basis of the maximum applied force. Instead of the maximum applied force, the maximum applied torque can also be ascertained from the design of the system for checking the bonded joint connection, and then the maximum breaking force can be calculated from this maximum applied torque.

Another possible embodiment of the invention provides that the plug region arranged or molded on the contact piece is removed before the contact piece is detached and that the inspection device then acts directly on the contact piece, for example on the soldering region of the contact piece, for detaching the contact piece from the conductor strand. This ensures that the contact is particularly reliably fixed to the inspection device, and therefore the process of detaching the contact can be particularly reliably performed. "plug region" refers to a region of the contact piece which is able to establish electrical contact with a counterpart, such as a blade plug or a socket. This region can be produced from the same base material, from which the joining connection to be checked or the soldering region of the joining connection is also formed. For the socket contact, a high-grade steel "super spring" is often arranged around this plug region, which has the shape of a housing. Just this plug area can be completely separated from the super spring.

As an alternative, however, it is also possible to dispense with the removal of the plug region mentioned. In this case, the contact plate can be clamped together with the plug region, for example, by means of the inspection device, before the contact is then detached from the conductor strand by breaking the connection by means of the inspection device.

According to another possible embodiment of the invention, it is provided that the fixing device has two clamping blocks, between which the welded joint is clamped and thereby fixed. In this way, the welded joint of the stranded conductor can be fixed particularly reliably. For this purpose, the clamping blocks must be easily moved only toward one another, so that the welded joint arranged between the clamping blocks is reliably secured.

A further possible embodiment of the invention provides that the inspection device has two clamping blocks, between which the contact piece is clamped at least indirectly and to which a tensile force is applied at least substantially transversely to the longitudinal direction of the conductor strand in order to detach the contact piece. This results in the already mentioned stripping process, according to which the contact piece is detached from the conductor strand in the event of a breaking of the bond connection. The contact piece, which is clamped at least indirectly between the two clamping blocks, is therefore easily pulled away from the conductor strand transversely to the main direction of extension and thus in the direction of the conductor strand by means of the inspection device, as a result of which the contact piece is gradually pulled away from the conductor strand in the region of the bonded joint connection.

According to another possible embodiment of the invention, it is provided that the free end region of the contact piece is first bent out transversely to the longitudinal direction of the conductor strand and is then subjected to a tensile force. The advantage is that the inspection device does not have to first perform the bending process mentioned. In other words, it can be provided, for example, that the free end region of the contact piece mentioned is first bent out transversely to the longitudinal direction of the conductor strand by means of another device or by a worker and is only loaded with a tensile force thereafter by means of an inspection device. This can be advantageous in particular if the inspection device itself does not allow particularly rapid movement movements. In this case, a large part of the movement is first achieved by bending the free end region of the contact piece before a pulling force has to be applied, which then relatively has to perform a small reciprocating linear movement. This saves time in the inspection method.

An alternative possible embodiment of the invention provides that the inspection device has a roller, the contact element is at least indirectly fixed to an outer circumferential surface of the roller and is detached from the conductor strand by rotation of the roller. By appropriate dimensioning of the roller diameter, the torque to be exerted on the roller can be adjusted accordingly. A correspondingly advantageous transmission ratio results if the roller has, for example, a large circumference or a large diameter, so that no particularly high torques have to be applied at all to the roller itself in order to release the contact from the conductor strand. In particular, a pre-bending of the contact piece is not necessary in this case, since the sheet of the contact piece is easily bent by itself by the rotation of the roller and the resulting movement. However, the welded joint can be pulled out of the clamped state by means of a large diameter, since a high force is thus required for separating the connection. The diameter is therefore selected such that the welded joint remains reliably in the clamped state during the entire separation process.

According to a further possible embodiment of the invention, it is provided that the holding device is moved relative to the inspection device during the detachment of the contact piece, in such a way that the relative position of a detachment line moving in the longitudinal direction of the conductor strand, at which the contact piece is detached from the conductor strand, remains at least substantially unchanged relative to the inspection device. This is particularly advantageous and advantageous in the present embodiment if the inspection device has the mentioned rollers. In this case, it is particularly advantageous to move the holding device relative to the inspection device during the detachment of the contact piece in such a way that the relative position of the moved detachment line remains at least substantially unchanged relative to the inspection device. For example, the fixing device itself can be moved actively and synchronously with the rotation of the roller. The synchronization of the rotation of the roller with the translational movement of the fastening device can be achieved, for example, by a mechanical coupling, for example, by a rack drive or the like.

Another possible embodiment of the invention provides that the fixing device is supported in a translatory movable manner and is tracked as a function of the moving detachment line for at least substantially constantly maintaining the relative position of the moving detachment line with respect to the examination device. The translationally movable support can be carried out, for example, by a carriage or the like which is supported in a translationally movable manner. The carriage itself can be actively driven in this case, so that the aforementioned movement synchronization between the rotation of the roller of the inspection device and the translational movement of the fastening device can be achieved. In a further embodiment, in which the inspection device has two clamping blocks, between which the contact piece is clamped at least indirectly and to which a tensile force is applied at least substantially transversely to the longitudinal direction of the conductor strand in order to release the contact piece, the fixing device can also be mounted in a translatory manner and can be tracked as a function of the moving release line in order to at least substantially maintain the relative position of the moving release line with respect to the inspection device. In this case, a force vector, according to which a tensile force is exerted on the contact piece, intersects the release line. In other words, the detachment line can thereby be arranged substantially vertically below the force application point at which the inspection device acts on the contact piece. In this way, particularly precise inspection results can be obtained, since the component of the force applied by means of the inspection device is applied at least substantially transversely to the longitudinal direction of the stranded conductor and thus transversely to the joint surface. This applies at least if the friction remains at a small level during the translational movement of the carriage.

The system according to the invention for testing a cohesive bond connection between a conductor strand and a contact element comprises a fastening device for fastening a soldered joint of the conductor strand having a plurality of individual wires that are joined together in a cohesive manner and an inspection device which is designed to act at least indirectly on the contact element and to detach the contact element from the conductor strand in order to break the bond connection. Advantageous embodiments of the method according to the invention can be considered as advantageous embodiments of the system according to the invention, in particular having means for carrying out the method steps, and vice versa.

Further advantages, features and details of the invention emerge from the following description of a possible embodiment and with the aid of the drawings. The features and feature combinations mentioned above in the description and the features and feature combinations shown below in the description of the figures and/or in the figures individually can be used not only in the respectively indicated combination but also in other combinations or alone without leaving the scope of the invention.

Drawings

The drawings show the following:

fig. 1 shows a perspective view of a bonded joint connection between a stranded conductor and a plate-shaped contact part, on which a plug region is also arranged or molded;

fig. 2 shows a further perspective view of the joining connection, in which the plug region is removed from the plate-like contact piece;

fig. 3 shows a schematic perspective view of a first embodiment of a system for testing the bonded joint connection, wherein the system has, in particular, a testing device by means of which the plate-shaped contact piece is pulled away upward from the strand conductor; and is

Fig. 4 shows a schematic perspective view of a further embodiment of the system, wherein the system has a roller-shaped inspection device for stripping the contact from the conductor strand.

In the drawings, identical or functionally identical elements have been provided with the same reference numerals.

Detailed Description

The cohesive joining connection 10 is shown in a perspective view in fig. 1. The cohesive bond connection 10 is located between the stranded conductor 12 and the plate-shaped contact piece 14. A schematically depicted plug region 16 is also arranged or molded on the plate-like contact piece 14. The stranded conductor 12 is surrounded by an insulating jacket 18, which surrounds the individual wires of the stranded conductor 12 in an insulating manner, which individual wires are not designated in greater detail here.

In a joining region, which is not designated in greater detail and is designed as a lap joint, the stranded conductor 12 has a so-called welded joint 20, which comprises a plurality of individual wires connected to one another in a material-locking manner. If the cohesive joining connection 10 is produced, for example, by means of ultrasonic welding, a cold weld is produced, so that the individual wires of the litz wire 12 are connected to one another in a cohesive manner in the region of a welding joint 20 and this welding joint 20 is in turn connected in a cohesive manner to the plate-shaped contact piece 14.

Fig. 2 shows the cohesive connection 10 in another perspective view, in which only the plug region 16 is removed from the plate-like contact 14. In particular in the automotive environment, it is important to be able to determine the quality of the joining element in the form of the conductor strand 12 and the contact element 14, which are connected to one another in a material-locking manner in this way. A method for checking the quality of an adhesively bonded joint connection 10 is explained in detail below with the aid of the following figures.

Fig. 3 shows a schematic perspective view of a first embodiment of a system 22 for checking an interlocking connection 10. The system comprises a fixing device 24 with two clamping blocks 26 for fixing the welding joint 20. Furthermore, the system 22 comprises an inspection device 28, which is only schematically depicted and which in turn has two clamping blocks 30, between which clamping blocks 30 a free end 32 of the plate-like contact piece 14 can be clamped.

In order to check the cohesive bond connection 10 between the stranded conductor 12 and the contact element 14, the solder joint 20 is first clamped between two clamping blocks 26 and is fixed thereby. The two clamping blocks 26 are moved towards each other, thus clamping the welding joint 20 between the clamping blocks 26. The free end 32 can then be bent, for example, upward into the position shown here, which can be done manually, for example, by a worker. The upwardly bent free end 32 is then clamped between two clamping blocks 30 of the inspection device 28. The joint connection is then broken for inspection by the contact 14 falling off the conductor strand 12 by means of the inspection device 28 acting on the free end 32 of the contact 14. In order to detach the contact element 14, the contact element 14 is subjected to a tensile force F at least substantially transversely to the longitudinal direction of the stranded conductor 12.

In the specific embodiment shown here, the plate-like contact piece 14 is therefore clamped directly between two clamping blocks 30 of the inspection device 28. Since the plate-shaped contact element 14 is pulled down at least substantially at right angles to a joining zone not shown in detail here, in which the conductor strand 12 is connected to the contact element 14 at its soldered joint 20, the free end 32 is bent away from the conductor strand 12, as already mentioned, preferably by 90 °. Alternatively, however, it is also possible for the free end 32 not to be bent beforehand by a person. In other words, it can also be bent automatically during the inspection method by an automatic orientation of the clamping blocks 30 in the direction of the line of force action of the applied tensile force F. It is also possible that the plug region 16, not shown here, is not removed first at all. In other words, in this case, the plate-like contact 14 can be clamped together with the plug region 16 between the clamping blocks 30 of the inspection device 28. The contact piece 14 can also be clamped with special clamping blocks on the free end 32, i.e. on the short web between the plug region 16 and the end face of the solder joint 20. The separation of the plug region 16 is likewise rendered superfluous by special clamping blocks.

Fig. 4 shows a schematic perspective view of another possible embodiment of the system 22 for testing a bonded joint connection 10 between a stranded conductor 12 and a plate-shaped contact element 14. This embodiment of the system 22 differs from the embodiment shown in fig. 3 by the rollers 34 and the clamping mechanism 36, which replace the two clamping blocks 30. The plate-shaped contact 14 is fixed to the roller 34, more specifically, to the outer circumferential surface 38 thereof, by means of a clamping mechanism 36, and the plate-shaped contact 14 is separated from the stranded conductor 12 by the rotation of the roller 34.

In this embodiment, therefore, the plate-like contact 14 is clamped to the roller 34, and the roller 34 is then rotated by the application of the moment M. Pre-bending of the plate-shaped contact piece 14 is not necessary in this case, since the contact piece 14 is bent by rotation of the roller 34 and thus spontaneously in a corresponding manner. During the stripping of the contact 14, the holding device 24 is moved relative to the inspection device 28 and thus relative to the rotating roller 34 in such a way that the relative position of a stripping line, not shown in detail here, which is moved in the longitudinal direction of the conductor strand 12 at which the contact 14 is released from the conductor strand 12, remains at least substantially unchanged relative to the inspection device 28.

The fastening device 24 can be supported on its clamping block 26, for example, on a carriage, not shown here, in a translatorily movable manner and can be tracked as a function of the moving release line for maintaining the relative position of the moving release line at least substantially unchanged relative to the inspection device 28. In particular, if the plate-shaped contact piece 14 is not in contact with the roller 34, i.e., is not in planar contact with the roller 34, the slide mentioned is preferably moved actively and synchronously with the rotation of the roller 34. The term "detachment line" can also refer to a fracture zone in which a peeling process or a process of detaching the plate-shaped contact element 14 from the conductor strand 12 takes place. Due to the force balance, the fracture zone or fracture line will usually be oriented at least substantially directly below the point of force application. In this case, in particular, the active movement of the carriage in synchronism with the rotation of the roller 34 is advantageous. This synchronization between the rotation of the roller 34 and the movement of the carriage can be achieved, for example, by: they are coupled to each other by a rack drive.

In both embodiments, it can be provided, for example, that the maximum force exerted by means of the inspection device 28, i.e., the maximum magnitude of the tensile force F or the maximum applied torque M in this case, when the contact 14 is detached, is ascertained and the quality of the cohesive connection 10 is ascertained on the basis of one of the two variables. In both embodiments of the system 22, the particular advantage of the procedure explained is that, instead of fixing the contact 14 and stripping off the stranded conductor 12, the procedure is carried out in exactly the opposite way, by: the soldered joint 20 of the stranded conductor 12 is fixed in a clamping block 26 and a tensile force F or a moment M is exerted on the contact element 14 for checking the bonded connection 10.

List of reference numerals:

10 splice connection

12 stranded conductor

14 contact

16 plug region

18 insulating sleeve

20-strand wire welded joint

22 system

24 fixing device

26 clamping block of fixing device

28 inspection device

30 clamping block of inspection device

Free end of 32 contact

34 roller

36 clamping mechanism

38 peripheral surface

F tension

M moment