EP1916748A1 - Method of connecting an electric connector and associated tool - Google Patents

Abstract

The method involves inserting a male part (1) of an electrical connector in a female part (2) of the connector using an insertion tool (3), by a human operator who physically applies an insertion force to the tool. The exceedance of a given threshold of the insertion force for ensuring a mechanical locking of the insertion of the part (1), is directly detected from a comparison between the insertion force and the threshold, using an insertion force sensor of the tool. An independent claim is also included for a male part insertion tool comprising an insertion force sensor.

Description

The invention relates to the field of methods for connecting an electrical connector and the field of tools for connecting an electrical connector. The connection of an electrical connector is particularly considered in the field of motor vehicle assembly, and in particular for the connection of connectors on automotive components such as a motor or a gearbox.

According to a known prior art, in the field of mounting a motor vehicle, it is known for an operator to connect manually and without special equipment electrical connectors on an organ.

Since a manual operation is never completely reliable, especially given the very high number of electrical connections to be made on a motor vehicle assembly line, the risk is important to obtain many non-compliances that are at best noted factory organ, or even terminal plant, and at worst at the customer, which then requires a return to the manufacturer to honor its warranty, all these nonconformities eventually proving very expensive for the manufacturer of a motor vehicle.

Often, the electrical connector is connected, that is to say that the electric loop is made, but the connector is not locked mechanically as it should be, that is to say it does not is not at all or not fully locked. This defect, which is not immediately apparent, will be revealed later. Indeed, a poorly mechanically locked connector does not withstand the normal operating vibrations of either the body or the vehicle or both at a time.

The various attempts of control by tests of electrical continuity did not give satisfaction.

According to a second prior art in the same field, instead of an electrical continuity test, a "pull-pushed" test is carried out by a verifier operator placed downstream of the assembly line of a motor vehicle. This test involves pulling on the electrical connector and pushing on the same electrical connector. This verification test remains a manual operation, subject to the same type of hazard as in the first prior art, although to a lesser extent. In addition, this "pull-pushed" test exerts a major stress on the connector which may risk damaging the electrical connection, or worse the wiring harness exiting the connector if the check operator pulls it instead of pulling on the connector, which unfortunately happens frequently because this last operation is more convenient to perform for the verifier operator. In addition, this additional manual verification operation costs time and money.

The invention proposes, to ensure very good reliability of the electrical connections made while simplifying the whole process and thus making it more practical, a connection method in which the exceeding of a given threshold of interlocking force which is sufficient to ensure the mechanical lock with a high probability is detected, thereby enabling to indirectly validate the mechanical lock. Thus a subsequent manual verification operation is no longer necessary, and is therefore preferably suppressed since the branching method according to the invention is sufficiently reliable and practical. The invention also provides the associated branching tool for an advantageous implementation of the branching method according to the invention.

According to the invention, there is provided a method of connecting an electrical connector, comprising a step of interlocking a male part of the connector in a female part of the connector, exceeding a given threshold of interlocking force. ensuring a mechanical locking said interlocking, characterized in that said step interlocking is performed using a tool capable of detecting said overshoot.

In a first preferred embodiment, said overshoot is directly detected. This process is the simplest and therefore the most economically viable. In a second embodiment, said overshoot is deduced from a comparison between a nesting force measurement and said threshold. This method is more complex and more expensive than the previous one, but it allows precise access to the measurement of the interlocking force and makes it possible to carry out monitoring and analysis of the remaining nonconformities which is more extensive. It also allows easier statistics, which can be interesting at the scale of a motor vehicle assembly plant.

Preferably, the method is carried out on an assembly line comprising a plurality of mounting stations. In this case, non-detection of non-compliance at the substation on which the electrical connection is made is very annoying because the correction will be possible at the earliest end of the chain if it ends up being detected. Thanks to this method, the operator can be warned, either by sound signal or by display, of the risk of non-compliance, which may lead him to correct the potential nonconformity of himself at the level of his position, before moving to the next position. The assembly line is advantageously a motor vehicle assembly line. It could also be for example an aircraft assembly line. Preferably, the detection of said exceeding validates the passage to the next assembly station, that is to say that the non-detection of said overshoot prevents passage to the next assembly station. On the contrary, if the exceeding of the threshold is not detected, and if the operator making the electrical connection does not realize it, the passage to the next station is not validated and thus is made impossible, the organ where the vehicle remaining stuck at the operator's post having made the connection that is likely to be non-compliant. Thus, whether or not the operator is aware of the potential nonconformity or risk of non-compliance, whether or not he is warned by an audible signal or a display, because the given threshold may include certain margin so that an interlocking force below the threshold could still in some cases have contributed to achieve a proper interlocking that is to say with mechanical locking, he is obliged to correct at the level of his position under It will be difficult to pass the organ or vehicle to the next station on the assembly line.

Preferably, no verification of electrical continuity of the connection is made, neither simultaneously nor later during the mounting process when the electrical connection method is part of a mounting process. This is possible thanks to the high reliability of the connection method according to the invention. However, it is not forbidden to keep, as an additional precaution, the verification of previous electrical continuity. However, its useless nature makes it possible to greatly simplify the process as a whole by doing without it.

The nesting step is preferably performed by a human operator physically applying a nesting force. Indeed, it is in the context of a manual operation that the risk of non-compliance is the highest. However, it is still possible to use the method also when the connection is made by a machine or a robot, which then makes it possible to detect a malfunction or a poor calibration of the latter.

In the option in which the electrical connector comprises a seal, in the case where the seal of the connector requires the prior application of a force greater than said threshold, the tool is capable of detecting twice said overshoot. Consequently, a bad connection will be detected, despite a first exceeding of the interlocking force threshold applied to overcome the friction of the seal on other parts of the connector during the nesting.

In a first option for using the connection method according to the invention, the connector belongs to an electrical device having an open electrical circuit when it is not working. Thus non-conformities, previously undetectable by an electrical continuity test, can be detected and corrected in time. In a second option for using the connection method according to the invention, the connector belongs to an electrical device having a closed electrical circuit when it is not working. Thus some nonconformities, previously undetectable by an electrical continuity test, can be detected and corrected in time.

In a preferred embodiment shown in the figures described below, the mechanical locking is obtained by snap-fitting cooperation between an element of the male part and an element of the complementary female part of the element of the male part. Other types of mechanical locking can also be envisaged, mechanical locking being obtained automatically when the interlocking force exerted exceeds a given threshold, this threshold may include a margin so as to render negligible the risk of mechanical non-locking despite the application of a nesting force at least equal to the given threshold.

According to the invention, there is also provided a tool for interlocking the male part of an electrical connector in its female part, comprising a detector for exceeding the given threshold of interlocking force applied to the tool.

In a first preferred embodiment, the tool comprises a user's handle which comprises said detector which is able to emit a signal in the event of detection. Preferably, the detector comprises a calibrated spring and a contactor arranged in such a way that the contactor reacts when the compressive force exerted on the spring by the interlocking force exceeds said threshold, usually when its terminals come into contact with the one of the other. This device is extremely simple while being effective. The handle advantageously comprises a sliding internal part adapted to compress the spring during the nesting. This is a simple way to transmit the interlocking force to the detector. If the detector is relatively fragile and does not support significant pressure, it is advantageously provided that the handle comprises a protective stop arranged to prevent an engagement force greater than a limit value deteriorates the detector. In a preferred embodiment, the stop comprises a pin cooperating with a light, the pin being able to move from one end to the other of the light advantageously in a rectilinear translational movement.

In a second embodiment, the tool comprises on the one hand a user's handle which comprises an interlocking force sensor applied to the tool emitting a measurement of said force, on the other hand a comparator of said measurement with said threshold, and an electrical connection connecting the comparator to the sensor. The comparator may be included in a computer located in the vicinity of the assembly line. This type of tool is more complex but allows access to a more precise measurement of the applied nesting force. A preferential way of transmitting the interlocking force to the sensor may be effected when the handle comprises two internal sliding parts arranged so as to clamp together the sensor during nesting without touching each other. To avoid sudden tightening of the sensor by shock, the handle advantageously comprises a spring that compresses one of the internal sliding parts during the nesting and which is arranged to dampen the clamping force on the sensor. If the detector is relatively fragile and does not support significant pressure, it is advantageously provided that the handle comprises a protective stop arranged so as to prevent an engagement force greater than a limit value deteriorates the sensor. In a preferred embodiment, the stop comprises a pin cooperating with a light, the pin being able to move from one end to the other of the light advantageously in a rectilinear translational movement.

• la figure 1 représente schématiquement un connecteur non branché électriquement et appartenant à un dispositif électrique présentant un circuit électrique ouvert lorsque le dispositif électrique ne fonctionne pas ;
• la figure 2 représente schématiquement un connecteur branché électriquement mais non verrouillé mécaniquement et appartenant à un dispositif électrique présentant un circuit électrique ouvert lorsque le dispositif électrique ne fonctionne pas ;
• la figure 3 représente schématiquement un connecteur branché électriquement et verrouillé mécaniquement et appartenant à un dispositif électrique présentant un circuit électrique ouvert lorsque le dispositif électrique ne fonctionne pas ;
• la figure 4 représente schématiquement un connecteur non branché électriquement et appartenant à un dispositif électrique présentant un circuit électrique fermé lorsque le dispositif électrique ne fonctionne pas ;
• la figure 5 représente schématiquement un connecteur branché électriquement mais non verrouillé mécaniquement et appartenant à un dispositif électrique présentant un circuit électrique fermé lorsque le dispositif électrique ne fonctionne pas ;
• la figure 6 représente schématiquement un connecteur branché électriquement et verrouillé mécaniquement et appartenant à un dispositif électrique présentant un circuit électrique fermé lorsque le dispositif électrique ne fonctionne pas ;
• la figure 7 représente schématiquement un exemple de phase de préparation dans le procédé de branchement selon l'invention ;
• la figure 8 représente schématiquement un exemple de phase d'emboîtement dans le procédé de branchement selon l'invention ;
• la figure 9 représente schématiquement un exemple de phase de retrait de l'outil dans le procédé de branchement selon l'invention ;
• la figure 10 représente schématiquement une vue de face longitudinale en coupe d'un exemple d'outil selon l'invention ;
• la figure 11 représente schématiquement une vue de côté longitudinale en coupe d'un exemple d'outil selon l'invention ;
• la figure 12 représente schématiquement une vue de côté longitudinale en coupe d'un exemple d'outil selon l'invention similaire à celle de la figure 11, mais présentant un ressort plus comprimé que sur la figure 11 ;
• la figure 13 représente schématiquement une vue transversale en coupe d'un exemple d'outil selon l'invention.
• la figure 14 représente schématiquement également une vue transversale en coupe d'un exemple d'outil selon l'invention.

The invention will now be described in more detail using the following figures, given by way of illustrative and nonlimiting examples, in which:

• schematically shows a connector not electrically connected and belonging to an electrical device having an open electrical circuit when the electrical device is not working;
• 2 schematically shows a connector electrically connected but not mechanically locked and belonging to an electrical device having an open electrical circuit when the electrical device is not working;
• schematically shows a connector electrically connected and mechanically locked and belonging to an electrical device having an open electrical circuit when the electrical device does not work;
• FIG. 4 schematically represents a connector not electrically connected and belonging to a device electric having a closed electrical circuit when the electric device is not operating;
• Figure 5 schematically shows a connector electrically connected but not mechanically locked and belonging to an electrical device having a closed electrical circuit when the electrical device does not work;
• FIG. 6 schematically represents a connector electrically connected and mechanically locked and belonging to an electrical device having a closed electrical circuit when the electrical device does not work;
• FIG. 7 schematically represents an example of a preparation phase in the branching method according to the invention;
• FIG. 8 schematically represents an example of an interlocking phase in the branching method according to the invention;
• Figure 9 shows schematically an example of withdrawal phase of the tool in the branching method according to the invention;
• FIG. 10 schematically represents a longitudinal front view in section of an exemplary tool according to the invention;
• Figure 11 shows schematically a longitudinal side view in section of an exemplary tool according to the invention;
• Figure 12 shows schematically a longitudinal side view in section of an exemplary tool according to the invention similar to that of Figure 11, but having a spring more compressed than in Figure 11;
• Figure 13 shows schematically a cross sectional view of an exemplary tool according to the invention.
• Figure 14 schematically also shows a cross sectional view of an exemplary tool according to the invention.

In all of Figures 1 to 14, the same elements are referenced with the same numbers and are not necessarily recalled when describing each of the figures.

Figure 1 schematically shows a connector not electrically connected and belonging to an electrical device having an open circuit when the electric device does not work. With the help of a tool 3, described in more detail in connection with FIGS. 10 to 13 and not shown in FIGS. 1 to 6, a male part 1 of an electrical connector comprising two electric wires 11 and 12 must being fitted into a female part 2 of this electrical connector comprising two electrical wires 21 and 22, the electrical continuity of the electrical circuit 20, here an open electrical circuit belonging to an electrical device 4 not shown in FIGS. 1 to 6, which must result from the connection on the one hand between the son 11 and 21 and on the other hand between the son 12 and 22. An element 13 belonging to the male part 1 should cooperate with an element 23, complementary to the element 13, belonging to the party female 23, to mechanically lock the interlocking of the male part 1 in the female part 2, which has not been the case here. The connector is not electrically connected and this non-compliance of the electrical connection can not be detected by an electrical continuity test.

2 schematically shows a connector electrically connected but not mechanically locked and belonging to an electrical device having an open electrical circuit when the electrical device does not work. The connector is electrically connected but is not mechanically locked and this non-compliance of the electrical connection can not be detected by an electrical continuity test.

3 schematically shows a connector electrically connected and mechanically locked and belonging to an electrical device having an open electrical circuit when the electrical device does not work. The connector is electrically connected and mechanically locked. Similarly, this conformity of the electrical connection can no more be detected by an electrical continuity test.

Figure 4 schematically shows a connector not electrically connected and belonging to an electrical device having a closed electrical circuit when the electrical device does not work. This time, an electrical continuity test will make it possible to detect the non-compliance of the electrical connection.

Figure 5 shows schematically a connector electrically connected but not mechanically locked and belonging to an electrical device having a closed electrical circuit when the electrical device does not work. In contrast to the previous figure, an electrical continuity test is here impotent to detect the non-compliance of the electrical connection.

Figure 6 shows schematically a connector electrically connected and mechanically locked and belonging to an electrical device having a closed electrical circuit when the electrical device does not work. An electrical continuity test does not make it possible to discriminate between the compliant electrical connection of this figure and a non-compliant electrical connection as in FIG. 5. The insufficiency, and consequently the inefficiency, of the electrical continuity tests comes from be amply demonstrated using the previous figures.

Figure 7 now schematically shows an example of a preparation phase in the branching method according to the invention. A male part 1 of a electrical connector comprising two electrical son 11 and 12 will be fitted into a female portion 2 of this electrical connector comprising two electrical son 21 and 22, the electrical continuity of the electrical circuit 20, here open electrical circuit, to result from the electrical connection of a part between the son 11 and 21 and secondly between the son 12 and 22. An element 13 belonging to the male part 1 will cooperate with an element 23, complementary to the element 13, belonging to the female part 2, for mechanically lock the interlocking of the male part 1 in the female part 2. The interlocking is carried out using a tool 3 comprising an interface 30 adapted to the connector, which interface 30 can be either fixed or interchangeable thus allowing use the same tool 3 with different interfaces 30 adapted to different types of connector.

FIG. 8 schematically represents an example of an interlocking phase in the branching method according to the invention. The exercise of an interlocking force in the direction of the arrow makes it possible to engage the male part 1 of an electrical connector comprising two electrical wires 11 and 12 in the female part 2 of this electrical connector comprising two electrical son 21 and 22, the electrical continuity of the electrical circuit 20, here open electrical circuit, being provided by the electrical connection on the one hand between the son 11 and 21 and on the other hand between the son 12 and 22, and the mechanical locking of the interlocking of the connector which mechanical locking is obtained by the cooperation, by snapping in FIG. 8, between, on the one hand, the element 13 belonging to the male part 1, and, on the other hand, the element 23 , complementary to the element 13, belonging to the female part 2. The branching method according to the invention is especially of interest in the case of a mechanical lock which is not easily verifiable. On the other hand, in the case of an electric lock, possible in complex and expensive electrical connectors, relatively simple electrical verification is often possible. By cons, the connecting method according to the invention allows the use of electrical connector mechanical locking, much simpler and cheaper, with a high degree of reliability.

Figure 9 shows schematically an example of withdrawal phase of the tool in the branching method according to the invention. Still following the arrow, by a movement in opposite direction, the tool is simply removed leaving the electrical connector nested and mechanically locked, that is to say ready to use. In FIGS. 7 to 9, the electrical harnesses respectively connected to each of the male and female portions of the electrical connector have not been shown for reasons of simplicity, but they exist, the connection being made most often between connector parts. to which electric beams have already been connected.

Figure 10 schematically shows a longitudinal front view in section of an exemplary tool according to the invention, and more specifically the handle of the tool. Figure 11 schematically shows a longitudinal side view in section of an exemplary tool according to the invention. FIG. 12 schematically represents a longitudinal side view in section of an exemplary tool according to the invention similar to that of FIG. 11, but having a spring that is more compressed than in FIG. 11. In FIGS. 10 and 11, the spring is uncompressed because the interlocking force is not applied. In Figure 12, on the contrary, the spring is compressed because the interlocking force is applied.

In the embodiment which is rather represented here, a hollow portion 31 of the handle comprises a housing in which two sliding internal parts 35A and 35B are slid, when an interlocking force is applied on the tool for connecting the electrical connector. The sliding of these internal parts in turn compresses a spring 34 which in return brings the clamping force sensor 32 between the inner parts 35A and 35B. An electrical connection 39 connects the sensor 32 to a comparator outside the handle shown. An excessive interlocking force is neutralized with respect to the pressure exerted on the sensor 32, when the pin 36 has passed from one end, as in FIGS. 10 and 11, to the other, as in FIG. the light 37. The elements 33, 33A and 33B do not exist in this embodiment. A recess 38 allows the passage of the electrical harness connected to one of the male or female parts of the electrical connector.

In another alternative embodiment, the sensor 32 does not exist, it is replaced by a contactor 33 which is triggered by the contacting of its opposite terminals 33A and 33B, bringing into contact which occurs when the spring 34 is compressed as in Figure 12.

Figure 13 schematically shows a cross sectional view of an exemplary tool according to the invention. This view is a sectional view along the plane A of FIG. 11. Its interest essentially lies in the highlighting of the recess 38 which allows the passage of the electrical harness connected to one of the male or female parts of the electrical connector, thus easily allowing the connection of an electrical connector whose parts, male or female, are already connected to their respective electrical harnesses.

FIG. 14 schematically also shows a transverse sectional view of an exemplary tool according to the invention. This view is a sectional view along the plane B of FIG. 11.

The given threshold of interlocking force varies according to the electrical connector considered. A series of tests for a given electrical connector makes it possible to determine the value of this threshold which may correspond, for example, to the maximum value obtained during the tests increased by a chosen safety margin as a function of the acceptable error rate for the electrical connection. considered.

Claims (22)

Method for connecting an electrical connector, comprising a step of interlocking a male part (1) of the connector in a female part (2) of the connector, the passing of a given threshold of interlocking force ensuring a locking mechanical said nesting, characterized in that said nesting step is performed using a tool (3) capable of detecting said overshoot. Branching method according to claim 1, characterized in that said overshoot is directly detected. Branching method according to claim 1, characterized in that said exceeding is deduced from a comparison between a nesting force measurement and said threshold. Connection method according to any one of the preceding claims, characterized in that it is carried out on an assembly line comprising a plurality of mounting stations. Connection method according to claim 4, characterized in that the assembly line is a motor vehicle assembly line. Branching method according to any one of claims 4 to 5, characterized in that the non-detection of said overshoot prevents passage to the next assembly station. Connection method according to any one of the preceding claims, characterized in that no electrical continuity check of the connection is made, either simultaneously or later. Branching method according to any one of the preceding claims, characterized in that the interlocking step is performed by a human operator physically applying a nesting force. Connection method according to any one of the preceding claims, characterized in that when a seal of the connector requires the prior application of a force greater than said threshold, the tool is capable of detecting twice said overshoot. Connection method according to any one of claims 1 to 9, characterized in that the connector belongs to an electrical device (4) having an open electrical circuit (20) when it does not work. Connection method according to any one of claims 1 to 9, characterized in that the connector belongs to an electrical device (4) having a closed electrical circuit (20) when it does not work. Connection method according to any one of the preceding claims, characterized in that the mechanical locking is obtained by snap-fitting cooperation between an element (13) of the male part (1) and a component (23) of the female part ( 2) complementary to the element (13) of the male part (1). An interlocking tool for the male part (1) of an electrical connector in its female part (2), comprising a detector (32, 33) for exceeding the given threshold of interlocking force applied to the tool. Tool according to claim 13, characterized in that it comprises a handle (31) for the user which comprises said detector which is able to emit a signal in the event of detection. Tool according to claim 14, characterized in that the detector comprises a calibrated spring (34) and a contactor (33) arranged so that the contactor is triggered when the compressive force exerted on the spring by the force of interlocking exceeds said threshold. Tool according to claim 15, characterized in that the handle comprises an inner sliding piece (35) adapted to compress the spring during the nesting. Tool according to any one of claims 13 to 16, characterized in that the handle comprises a protective stop (36, 37) arranged to prevent an interlocking force greater than a limit value from damaging the detector. Tool according to claim 13, characterized in that it comprises a user's handle which comprises an interlocking force sensor (32) applied to the tool emitting a measurement of said force, a comparator of said measurement with said threshold an electrical connection (39) connecting the comparator to the sensor. Tool according to claim 18, characterized in that the handle comprises two internal sliding parts (35A, 35B) arranged so as to clamp together the sensor during the nesting without touching each other. Tool according to claim 19, characterized in that the handle comprises a spring (34) that compresses one of the internal sliding parts (35A) during the interlocking and which is arranged so as to damp the clamping force on the sensor. Tool according to any of claims 18 to 20, characterized in that the handle comprises a protective stop (36, 37) arranged to prevent an interlocking force greater than a limit value from damaging the sensor. Tool according to claim 17 or 21, characterized in that the stop comprises a pin (36) cooperating with a lumen (37).

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