FR3115369A1 - Method and device for monitoring the wear and behavior of an electrical connector - Google Patents

Abstract

The invention relates to a device and a method for monitoring the wear and behavior of an electrical connector. The method comprises the following steps: obtaining (410) measurements relating to the conditions of use of the electrical connector and obtaining measurements of the environment close to the electrical connector; transmit (420) the measurements obtained to a remote unit of the electrical connector; determining (430) whether all the measurements obtained comply with the recommendations for use issued by a manufacturer of the electrical connector; for each measurement that does not comply with a usage recommendation, incrementing (440) a number of incidents by one unit, the electrical connector then having to be overhauled if the number of incidents is greater than or equal to a number of incidents maximum; send (450) an alert message to the manufacturer and to an operator of this electrical connector when the electrical connector must be overhauled. Figure for the abstract: Fig. 4

Description

Method and device for monitoring the wear and behavior of an electrical connector

The invention relates to the field of structuring the monitoring of the wear and the behavior of the electrical connector and more particularly that of the monitoring of the wear and the behavior of the electrical connector used on a test bench of an electrical device.

Technology background

The life cycle of a technological product is divided into three phases. It begins with a design and manufacturing phase, continues with a use phase and ends with an end-of-life (recycling) phase.

While the company designing the product masters the design and manufacturing phase, it loses visibility as soon as the product is sold and used by an operator. Very often, the only feedback available is through questionnaires, consumer reviews or during maintenance operations carried out on the product. Added to this loss of visibility is a lack of information on the conditions of use of the product, i.e. on the environment in which the product is or has been used or whether the product is or has been used in accordance with the manufacturer's recommendations for use. This loss of visibility and this lack of information on the conditions of use of the product can make decision-making tricky when, for example, maintenance interventions on the product. They can also lead to a lack of knowledge that is detrimental to recycling operations or the design of product upgrades. Indeed, the lack of information on the conditions of use can make the decision to reuse this or that component of the product difficult or risky. Furthermore, knowing in advance the condition of the product to be recycled will

optimize the planning of dismantling operations and product recycling.

These problems of loss of visibility and lack of information on the conditions of use of the product are induced by the heterogeneity of the applications from one product to another, the various stakeholders and the application domains.

The problems of loss of visibility and lack of information on the conditions of use set out above are present for any product, in particular for the electrical connectors used on a test bench for electrical equipment used, in particular in the automotive sector. .

An electrical connector for a test bench is a product that makes it possible to establish a mechanical and electrical connection between a socket and its electrical harness on board the electrical device to be tested and an electrical harness socket of an electrical cabinet of the test bench. test in order to test the proper functioning of the product.

The electrical connector is made up of a set of fixed and mobile elements which allow the locking and unlocking of the electrical connector. Locking the electrical connector enables the mechanical and electrical connection to be established, while unlocking allows this connection to be broken. These fixed and mobile elements must be robust enough to allow a large number of electrical connections between the electrical cabinet and the electrical devices to be tested. However, during use, the electrical connector experiences physical stress and wear. Regular maintenance (or overhaul) of the connector is essential to ensure its perfect operation over time.

The objective of the invention is to provide solutions to the various problems described above.

In particular, one of the objectives of the invention is to provide and associate a device for monitoring the wear and behavior of an electrical connector with an electrical connector used on an electrical device test bench. This device allows the collection of measurements relating to the conditions of use of the electrical connector and to measurements of its environment. A comparison of these measurements with recommendations for use issued by the manufacturer of this electrical connector makes it possible to detect incidents when using the electrical connector. A decision on whether to overhaul the electrical connector is then made according to the number and type of incidents counted.

According to a first aspect, the invention consists of methods for monitoring the wear and behavior of an electrical connector used on a test bench for an electrical device, the electrical connector being intended to electrically connect the electrical device with an electrical cabinet of the test bench, the process comprises the following steps:

• obtain measurements relating to the conditions of use of the electrical connector and obtain measurements of the environment close to the electrical connector;

• transmit the measurements obtained to a unit remote from the electrical connector;
• determine whether all the measurements obtained comply with the recommendations for use issued by the manufacturer of the electrical connector;
• for each measurement that does not comply with a recommendation for use, increment a number of incidents in units, the electrical connector then having to be overhauled if the number of incidents is greater than or equal to a predefined number of incidents;
• issue an alert message to the manufacturer and an operator of the electrical connector when the latter needs to be overhauled.

Thus, the method evaluates a state of degradation of the electrical connector according to the number of incidents counted during the use of the electrical connector and the operator and/or the manufacturer of this electrical connector is (are) alerted to schedule a review phase. Thus, the method allows the operator or the manufacturer to plan and anticipate, for example, the management of a stock of spare parts for the electrical connector and to place any orders with suppliers, or even the planning of operators to carry out the overhaul of the electrical connector. The manufacturer can also supply the operator with a replacement electrical connector when the electrical connector requires overhaul. The operator can also rotate the electrical connector with another electrical connector so as to avoid premature wear of an in-line electrical connector. The method therefore provides information on the conditions of use of the electrical connector, information which can be used, for example, to determine whether certain elements of an electrical connector can be recycled when the electrical connector reaches the end of its life or even to define new developments for certain elements of the electrical connector to make them more robust, for example. The process also makes it possible to diagnose a problem with the electrical connector or even to highlight improper use by the operator.

According to one embodiment, one of the measurements is a count of the number of times the electrical connector is locked during a period of time, and it is determined that the electrical connector must be overhauled when a rate of use defined by a ratio of said counting on a maximum number of electrical connector lockouts is greater than the manufacturer's recommended maximum number of lockouts for that time period.

According to one embodiment, the electrical connector comprises at least one electrical contact in which an electrical current flows during the test of the electrical device, one of the measurements is a measurement of the intensity of the current flowing in each contact of the connector when the electrical device is being tested, it is determined that a measurement does not comply with a recommendation for use as soon as one of the following conditions is verified:

• if the intensity of the current measured at the level of the contact exceeds a first threshold beyond the maximum admissible intensity recommended by the manufacturer, for a duration greater than a first maximum duration;
• if the intensity of the current measured at the level of the contact exceeds a second threshold, greater than the first threshold, for a duration greater than a second maximum duration less than the first maximum duration then in number; Or
• if the intensity of the current measured at the level of the contact exceeds a third threshold beyond the maximum admissible intensity recommended by the manufacturer, for a duration greater than a third maximum duration less than the second maximum duration.

According to one embodiment, the electrical connector comprises at least two electrical contacts in which electrical currents flow during the test of the electrical apparatus, one of the measurements is a first measurement of disparity of the intensities of the electrical currents flowing in the contacts of the electrical connector during a test of a first electrical device and a second measurement of the disparity of the intensities of the electrical currents flowing in the contacts of the electrical connector during a test of a second electrical device, it is determined that a measurement does not respect a recommendation for use when the first and second measurements indicate a disparity in the intensities of the electric currents flowing in the contacts of the electrical connector greater than a threshold value recommended by the manufacturer.

According to one embodiment, the number of incidents and/or the number of incidents relating to one of said contacts and/or the rate of use is sent periodically to the manufacturer and/or the operator.

According to a second aspect, the invention relates to a device for monitoring the wear and behavior of an electrical connector used on a test bench for an electrical device, the electrical connector being intended to electrically connect the electrical device with an electrical cabinet of the test bench. The device includes:

• means, embedded on the electrical connector, for obtaining measurements relating to the conditions of use of the electrical connector;
• means, embedded on the electrical connector, for obtaining measurements of the environment close to the electrical connector;
• means, embedded in the electrical connector (130), for transmitting the measurements obtained to means, embedded in a unit (150) remote from the electrical connector (130);

• means, embedded on the unit, for determining whether all the measurements obtained comply with the recommendations for use issued by the manufacturer of the electrical connector and, for each measurement which does not comply with a recommendation for use, incrementing by one unit a number of incidents, the electrical connector then having to be overhauled if the number of incidents is greater than or equal to a maximum number of incidents;

• means, on board the unit, to send an alert message to the manufacturer and to an operator of the electrical connector when the electrical connector needs to be overhauled.

According to another aspect, the invention relates to a test bench for an electrical appliance comprising an electrical cabinet and an electrical connector intended to electrically connect the electrical appliance with the electrical cabinet (, said bench further comprising a device for monitoring of the wear and behavior of the electrical connector according to the second aspect.

According to another aspect, the invention relates to a computer program comprising instructions adapted for the execution of the steps of the method of the first aspect, when the computer program is executed by at least one processor.

According to another aspect, the invention relates to a recording medium readable by a computer or a mobile communication device on which is recorded a computer program comprising instructions for the execution of the steps of the method according to the first aspect.

Brief description of figures

Other characteristics and advantages of the invention will emerge from the description of the non-limiting embodiments of the invention below, with reference to the appended figures 1 to 6, in which:

schematically illustrates a test bench 100 of an electrical device 110 according to a particular non-limiting embodiment of the present invention;

schematically illustrates an electrical connector 130 according to a particular non-limiting embodiment of the present invention;

schematically illustrates an exploded view of the electrical connector 130 of [Fig. 2];

illustrates a block diagram of the steps of a method 400 for monitoring the wear and behavior of an electrical connector used on a test bench 100 of an electrical device 110 according to a particular non-limiting embodiment of the present invention ;

schematically illustrates a phase of the life cycle of an electrical connector 130 when it is used to test electrical devices 110 according to a particular non-limiting embodiment of the present invention; And

schematically illustrates an architecture of the device 140 according to a particular and non-limiting embodiment of the present invention.

Devices and methods will now be described in the following with reference in conjunction to FIGS. 1 to 6 . Elements having the same characteristics and offering the same technical effects are identified with the same reference signs throughout the following description.

Subsequently, the expression "a device comprises an element" does not exclude that this device may also include (be made up of) other elements not mentioned.

The embodiments and variants described can be combined with each other without this being systematically mentioned.

schematically illustrates a test bench 100 of an electrical device 110 according to a particular non-limiting embodiment of the present invention.

For example, the electrical device 110 is an electric motor, an electric seat or a dashboard of an automobile.

For example, the 100 test bench is installed on certain stations of an electric motor production line to electrically test these electric motors.

The test bench 100 comprises an electrical cabinet 120, an electrical connector 130 intended to electrically connect the electrical device 110 with the electrical cabinet 120.

The test bench 100 further comprises a device 140 for monitoring the wear and behavior of the electrical connector 130. The device comprises means 141, embedded on the electrical connector 130, to obtain measurements relating to the conditions of use of the electrical connector 130; means 142, embedded on the electrical connector 130, to obtain measurements of the environment close to the electrical connector 130; means 143, embedded in the electrical connector 130, for transmitting the measurements obtained to means 143, embedded in a unit 150 remote from the connector; means 144, onboard unit 150, for determining whether all the measurements obtained comply with the usage recommendations issued by a manufacturer of the electrical connector 130 and, for each measurement which does not comply with a usage recommendation, incrementing by one unit a number of incidents, the electrical connector 130 then having to be overhauled if the number of incidents NI is greater than or equal to a maximum number of incidents; and means 145, on board the unit (150), to send an alert message to the manufacturer and to an operator of this electrical connector 130 when the electrical connector 130 needs to be overhauled.

Means are said to be embedded on the electrical connector 130 (or on the unit 150) to indicate that they are part of the electrical connector 130 (of the unit 150) and as such these means can communicate information between them without have recourse to the means 143. In contrast, the unit 150 is said to be remote from the electrical connector 130 to indicate that this unit 150 is not part of the electrical connector 130. The means on board the unit 150 communicate with the on-board means on the electrical connector 130 via means 143 embedded both on the electrical connector 130 and on the unit 150.

According to one embodiment, the means 144 and 145 are also embedded on the electrical connector 130. According to this embodiment, the means 141 and 142 directly communicate the measurements obtained to the means 144. Neither the unit 150 nor the means 143 n no longer have any reason to exist.

According to another embodiment, means 144 are embedded on connector 130 and means 145 are embedded on unit 150. According to this embodiment, means 141 and 142 directly communicate the measurements obtained by means 144.

According to a variant of this last embodiment, the means 143 on board the electrical connector 130 emit an alert message to the manufacturer and to the operator of this electrical connector 130 when the connector must be overhauled and the means 145 and the unit 150 no longer exist.

According to another variant of this last embodiment, the means 143 send information to the means 145 when the connector must be revised so that these means 145 send an alert message to the manufacturer and to the operator of this electrical connector 130.

According to a variant, the means 141 and 142 are also provided for formatting (pre-processing) the measurements obtained.

According to one embodiment, one of the means 141 detects the locking of the electrical connector 130.

For example, this means 141 is a "limit switch" type sensor positioned between two moving parts of the electrical connector 130, for example between the jaw bodies 131 and 134 of the electrical connector 130 of the .

According to one embodiment, the electrical connector 130 comprises electrical contacts for electrically connecting the electrical cabinet 120 and the electrical device 110.

According to this embodiment, one of the means 141 measures the intensity of the current flowing in each contact of the electrical connector 130 when the electrical device 110 is being tested.

For example, this means 141 is a Hall effect sensor or an ammeter clamp located downstream of the electrical connector 130.

According to one embodiment, one of the means 141 is a probe which measures the temperature at the level of an element of the electrical connector 130 when the electrical device 110 is being tested, for example the temperature of a jaw of the electrical connector 130 of the .

According to one embodiment, one of the means 141 is an accelerometer which measures the acceleration of the electrical connector 130.

Measuring the acceleration of the electrical connector 130 makes it possible to know whether the electrical connector 130 has suffered a fall or a shock during its use.

According to one embodiment, one of the means 142 is a probe which measures the luminosity of the environment close to the electrical connector 130.

According to one embodiment, one of the means 142 is an optical sensor which measures the temperature of the environment close to the electrical connector 130.

According to one embodiment, one of the means 142 is a probe which measures the hygrometry of the environment close to the electrical connector 130.

According to one embodiment, one of the means 142 is a probe which measures the atmospheric pressure of the environment close to the electrical connector 130.

According to one embodiment, the device 140 comprises means 146 provided for obtaining a geographical location of the electrical connector 130. According to one example, this means 146 is a GPS (Global Positioning System) sensor embedded on the electrical connector 130 or positioned near of the electrical connector 130.

and [Fig. 3] schematically illustrate an electrical connector 130 according to a particular non-limiting embodiment of the present invention.

There illustrates a perspective view of electrical connector 130 while [Fig. 3] illustrates an exploded view of electrical connector 130.

The electrical connector 130 comprises a high jaw body 131 housed in a locking drawer 132 and comprising a first group of 4 electrical contacts 133 designed to carry an electric current when the electrical device 110 and the electrical cabinet 120 are electrically connected. The electrical connector 130 further comprises a lower jaw body 134 held in a fixed position on a mounting bracket 150 of the test bench 100 and comprising a second group of electrical contacts 135 provided to carry an electric current when the electrical device 110 and the electrical cabinet 120 are electrically connected. The electrical connector 130 further comprises electrical sheaths 136 connected to the second group of electrical contacts 135 and having ends adapted to connect the electrical sheaths 136 to the electrical cabinet 120.

The locking slide 132 is hinged about an axis of the lower jaw body 134 to switch from an open position in which the contacts of the first and second groups of contacts do not hold in position the electrical terminals of the electrical device. 110, and a closed (locked) position in which said electrical terminals of the electrical device 110 are held in contact with the contacts of the first and second group of contacts by pinching said electrical terminals between the contacts of the first and second group of contacts then allowing an electrical connection between the electrical device 110 and the electrical cabinet 120.

The course of a test of an electrical device 110 is broken down into five steps:

In a step 1, the electrical device 110 is transported close to the test bench 100 and clamped by a fixing system to avoid any movement likely to disturb the test.

In a step 2, an operator manually connects each terminal of the electrical device 110 to a contact of the second group of electrical contacts 135, closes the electrical connector 130 and locks the upper jaw body 131 on the lower jaw body 134 so that each terminal is firmly pinched between the contacts of the first and the second group of contacts. The locking drawer 132 ensures, by mechanical pressure, good electrical continuity between each lug and the contacts.

In a step 3, the operator launches the test at the level of the electrical cabinet 120.

In a step 4, the actual test, from the point of view of the electrical device 110, begins when the electrical cabinet 120 applies an electrical voltage to the electrical device 110, and ends when there is no more applied voltage. The electrical cabinet 120 automatically manages the entire test performed on the electrical device 110 by modulating, for example, the power supply of the electrical device 110 which gives rise to different current profiles in the phases of the device. electric 110. Once the test is finished, the operator is warned by an audible or luminous signal located on the station or the test cabinet 120.

In a step 5, the operator unlocks the electrical connector 130 by unlocking the upper jaw body 131, removes the electrical terminals from the electrical device 110 and releases the electrical device 110 from its fastening system.

illustrates a block diagram of the steps of a method 400 for monitoring the wear and behavior of an electrical connector used on the test bench 100 of an electrical device 110 according to a particular non-limiting embodiment of the present invention .

In a step 410, the electrical device 110 is being tested. The means 141 obtain measurements relating to the conditions of use of the electrical connector 130 and the means 142 obtain measurements of the environment close to the electrical connector 130. Step 410 is followed by a step 420

In step 420, the means 143 on board the electrical connector 130 send the measurements obtained to the means 143 on board the unit 150. The means 144 of the unit 150 obtain the measurements. Step 420 is followed by a step 430.

In step 430, the means 144 determine whether all the measurements obtained comply with the recommendations for use issued by a manufacturer of the electrical connector 130.

In this case step 430 is followed by step 410 and in the opposite case, step 430 is followed by step 440.

In step 440, the means 144 increment a number of incidents NI by one unit for each measurement obtained which does not comply with a usage recommendation.

As long as the number of incidents NI is not equal to or greater than a maximum number of incidents, step 440 is followed by step 410. When the number of incidents NI is greater than or equal to this maximum number incidents, the electrical connector 130 must be overhauled and step 440 is followed by a step 450.

In step 450, the means 145 of the unit 150 send an alert message to the manufacturer and to an operator of this electrical connector 130.

According to one embodiment, the means 144 and 145 are also embedded on the electrical connector 130. According to this embodiment, the means 141 and 142 directly communicate the measurements obtained during step 410.

According to another embodiment, the means 144 are embedded on the connector 130 and the means 145 are embedded on the unit 150. According to this embodiment, the step 420 does not exist because the means 141, 142 and 144 are all embedded on the electrical connector 130.

According to a variant of this embodiment, in step 450, the means 143 send an alert message to the manufacturer and to an operator of this electrical connector 130 when the connector must be overhauled.

According to another variant of this embodiment, in step 450, the means 143 send information to the means 145 when the connector must be revised so that these means 145 send an alert message to the manufacturer and to an operator of this electrical connector 130.

According to one embodiment, in step 410, one of the means 141 detects the locking of the electrical connector 130. In step 430, each locking of the electrical connector 130 is counted over a period of time and a rate of usage TU is calculated at the end of this period of time by dividing the number of lockings of the electrical connector 130 by a maximum number NB of lockings recommended by the manufacturer for this period of time. This maximum number NB can be the maximum number of daily or weekly lockings for example.

In step 430, as long as the usage rate TU does not exceed a maximum number NB, step 430 is followed by step 410. The means 144 determine that a measurement does not respect a recommendation of use when the rate of use TU exceeds or is equal to the maximum number NB.

According to one embodiment, in step 410, one of the means 141 measures the intensity of the current flowing in each contact of the electrical connector 130 when the electrical device 100 is being tested. In step 430, the means 144 determine that a measurement does not comply with a usage recommendation as soon as one of the following conditions is verified:

• if the intensity of the current measured at the level of the contact exceeds a first threshold beyond the maximum admissible intensity recommended by the manufacturer, for a duration greater than a first maximum duration;
• if the intensity of the current measured at the level of the contact exceeds a second threshold, greater than the first threshold, for a duration greater than a second maximum duration less than the first maximum duration then a number; Or
• if the intensity of the current measured at the level of the contact exceeds a third threshold beyond the maximum admissible intensity recommended by the manufacturer, for a duration greater than a third maximum duration less than the second maximum duration.

According to one embodiment, in step 410, one of the means 141 measures a first measurement M1 of disparity in the intensities of the electric currents flowing in the contacts of the electrical connector 130 during a test of a first electrical device 110 and a second measurement M2 of disparity in the intensities of the electrical currents flowing in the contacts of the electrical connector during a test of a second electrical device 110. In step 430, the means 144 determine that a measurement does not comply with a recommendation for use when the first M1 and the second M2 measurements indicate a disparity in the intensities of the electric currents flowing in the contacts of the electrical connector greater than a threshold value recommended by the manufacturer.

According to one embodiment, in step 410, one of the means 141 measures the temperature at an element of the electrical connector 130 when the electrical device 110 is being tested. In step 430, the means 144 determine that a measured temperature does not comply with a usage recommendation when the measured temperature exceeds a maximum value recommended by the manufacturer.

According to one embodiment, in step 410, one of the means 141 measures the acceleration of the electrical connector 130. In step 430, the means 144 determine that a measured acceleration does not comply with a recommendation for use when the measured acceleration exceeds a maximum value recommended by the manufacturer.

According to one embodiment, in step 410, one of the means 141 measures the brightness of the environment close to the electrical connector 130. In step 430, the means 144 determine that a measured brightness does not respect a recommendation for use when the measured luminosity exceeds a maximum value recommended by the manufacturer.

According to one embodiment, in step 410, one of the means 141 measures the temperature of the environment close to the electrical connector 130. In step 430, the means 144 determine that a measured temperature does not respect a recommendation for use when the measured temperature exceeds a maximum value recommended by the manufacturer.

According to one embodiment, in step 410, one of the means 141 measures the humidity of the environment close to the electrical connector 130. In step 430, the means 144 determine that a measured humidity does not respect a recommendation for use when the measured temperature exceeds a maximum value recommended by the manufacturer.

According to one embodiment, in step 410, one of the means 141 measures the atmospheric pressure of the environment close to the electrical connector 130. In step 430, the means 144 determine that a measured atmospheric pressure does not respect not a recommendation for use when the measured temperature exceeds a maximum value recommended by the manufacturer.

According to one embodiment, in step 410, one of the means 141 measures the geographical position of the electrical connector 130. In step 430, the means 144 determine that a measured geographical position does not respect a recommendation of use when the geographical position does not belong to a list of geographical positions known to the manufacturer.

Since the electrical connector 130 can be used in different regions of the world, its geographical position as well as the temperature, humidity and/or atmospheric pressure of the environment close to the electrical connector 130 can modify the behavior of the constituent elements of the electrical connector 130 Determining the geographical position of the electrical connector and/or measuring parameters of the environment close to the electrical connector 130 therefore makes it possible to determine whether the electrical connector 130 is used in an environment which complies with the manufacturer's recommendations.

According to one embodiment, in a step 460, the means 145 periodically transmit the incident number NI and/or NIc and/or the rate of use TU to the manufacturer and/or the operator.

schematically illustrates a phase of the life cycle of an electrical connector 130 when it is used to test electrical devices 110 according to a particular non-limiting embodiment of the present invention.

This phase of use of the life cycle of the electrical connector 130 is broken down into a succession of periods of use, "normal" overhauls and "exceptional" overhauls (exceptional maintenance).

Each period of use 1 corresponds to successive uses of the electrical connector 130 then positioned on the mounting bracket of the test bench 100 during several tests of electrical devices 110. Each use of the electrical connector 130 is considered to correspond to a test of an electrical device 110. During a period of use 1, locking and unlocking of the electrical connectors 130 follow one another to test electrical devices 110. The rate of use TU increases until it reaches the number maximum NB of interlocks. An alert message is then issued and the electrical connector can be sent for a "normal" overhaul to the manufacturer.

A period of use 2 is marked by a succession of incidents. Each incident corresponds to a test of an electrical device 110 during which the electrical connector 130 was used outside the manufacturer's recommendations. When the number of incidents NI is greater than or equal to a maximum number of incidents, an alert message is issued and the electrical connector 130 is then considered to be "out of service" and must be returned to the manufacturer for an overhaul. exceptional (exceptional maintenance). During this exceptional overhaul, the electrical connector 130 is examined and any damaged component may be replaced.

A period of use n corresponds to the last period of use of the electrical connector 130. The maximum number of periods of use having been reached, the electrical connector 130 is then considered to be at the end of its life and it is returned to the manufacturer.

schematically illustrates an architecture of the device 140 according to a particular and non-limiting embodiment of the present invention.

According to the invention, the device 140 comprises the means 141, 142, 144, 145, and 146 which are configured for the implementation of the steps of an embodiment of the method described with regard to the .

According to a variant, part of these means of the devices 140 are embedded in the electrical connector 130 and another part of these means are embedded in a remote unit 150 remote.

The means of the electrical connector 130 and those of the unit 150 then communicate by means 143 embedded both on the electrical connector 130 and on the unit 150. The means 143 can be wired or wireless means and can use by example the I2C or SPI communication protocols.

The means of device 140, individually or in combination, can be integrated in a single integrated circuit, in several integrated circuits, and/or in discrete components. The device 140 can be produced in the form of electronic circuits or software (or computer) modules or else a combination of electronic circuits and software modules.

According to various particular embodiments, the device 140 is coupled in communication with other devices, for example via a communication bus or via dedicated input/output ports.

The device 140 comprises one (or more) processor(s) 601 configured to execute instructions for carrying out the steps of the method and/or for executing the instructions of the software or software embedded in the device 140. The processor 601 can include integrated memory, an input/output interface, and various circuits known to those skilled in the art. The device 140 further comprises at least one memory 602 corresponding for example to a volatile and/or non-volatile memory and/or comprises a memory storage device which can comprise volatile and/or non-volatile memory, such as EEPROM, ROM , PROM, RAM, DRAM, SRAM, flash, magnetic or optical disk. The memory 602 can for example be used to store the measurements obtained by the means 141 and 142 for a period of time and the means 145 can transmit these measurements periodically according to one embodiment.

The means 145 can send an alert message in the form of an email.

The computer code of the on-board software or software comprising the instructions to be loaded and executed by the processor is for example stored on the memory 602.

According to a particular and non-limiting embodiment, the device 140 comprises a block 603 of interface elements for communicating with external devices such as a remote server or else a near-field communication reader or a radio receiver. A wired or wireless communication network can be used. Interface element block 603 is also configured to receive information such as usage recommendations from a manufacturer and to issue commands and messages to a remote unit.

Of course, the present invention is not limited to the embodiments and other examples or variants described above but extends to all modes and/or variant embodiments which would have the same scope. In particular, the scope of the invention is not limited to the electrical connector illustrated in but extends to any electrical connector suitable for use on an electrical device test bench.

The shape of the elements of the devices as well as their size or their connection are also given for illustrative purposes only. Other shape and binding can be used for each of these elements.

Claims (9)

Method for monitoring the wear and behavior of an electrical connector used on a test bench of an electrical device, the electrical connector being intended to electrically connect the electrical device with an electrical cabinet of the test bench, the method involves the following steps:

• obtaining (410) measurements relating to the conditions of use of the electrical connector (130) and obtaining measurements of the environment close to the electrical connector (130);
• transmitting (420) the measurements obtained to a unit (150) remote from the electrical connector (130);
• determining (430) whether all the measurements obtained comply with recommendations for use issued by a manufacturer of the electrical connector (130);
• for each measurement that does not comply with a usage recommendation, incrementing (440) a number of incidents by one unit, the electrical connector (130) then having to be serviced if the number of incidents is greater than or equal to a number number of incidents;
• emitting (450) an alert message to the manufacturer and to an operator of this electrical connector when the electrical connector (130) must be overhauled.

A method according to claim 1, wherein one of the measurements is a count of the number of times the electrical connector is locked over a period of time, and it is determined that the electrical connector should be serviced when a usage rate defined by a ratio of said count to a maximum number of locks of the electrical connector is greater than the maximum number of locks recommended by the manufacturer for said period of time. Method according to claim 1, in which the electrical connector comprises at least one electrical contact in which an electrical current flows during the test of the electrical apparatus, one of the measurements being a measurement of the intensity of the current flowing in each contact of the electrical connector when the electrical device is being tested, and it is determined (430) that a measurement does not comply with a recommendation for use as soon as one of the following conditions is verified:

• if the intensity of the current measured at the level of the contact exceeds a first threshold beyond the maximum admissible intensity recommended by the manufacturer, for a duration greater than a first maximum duration;
• if the intensity of the current measured at the level of the contact exceeds a second threshold, greater than the first threshold, for a duration greater than a second maximum duration less than the first maximum duration then a number; Or
• if the intensity of the current measured at the level of the contact exceeds a third threshold beyond the maximum admissible intensity recommended by the manufacturer, for a duration greater than a third maximum duration less than the second maximum duration.

Method according to claim 1, in which the electrical connector comprises at least two electrical contacts in which electrical currents flow during the test of the electrical device, one of the measurements is a first measurement of the disparity of the intensities of the electrical currents flowing in the contacts of the electrical connector during a test of a first electrical device and a second measurement of disparity of the intensities of the electrical currents flowing in the contacts of the electrical connector during a test of a second electrical device, it is determined (430) that a measurement does not comply with a recommendation for use when the first and second measurements indicate a disparity in the intensities of the electric currents flowing in the contacts of the electrical connector greater than a threshold value recommended by the manufacturer. Method according to one of Claims 1 to 4, in which the number of incidents and/or the number of incidents relating to one of said contacts and/or the rate of use is sent periodically to the manufacturer and/or to the operator. Device (140) for monitoring the wear and behavior of an electrical connector (130) used on a test bench for an electrical device, the electrical connector being intended to electrically connect the electrical device with an electrical cabinet ( 120) of the test bench (100), the device comprises:

• means (141), embedded on the electrical connector (130), for obtaining measurements relating to the conditions of use of the electrical connector (130);
• means (142), embedded on the electrical connector (130), for obtaining measurements of the environment close to the electrical connector (130);
• means (143), embedded in the electrical connector (130), for transmitting the measurements obtained to means (143), embedded in a unit (150) remote from the electrical connector (130);

• means (144), embedded on the unit (150), for determining whether all the measurements obtained comply with recommendations for use issued by a manufacturer of the electrical connector (130) and, for each measurement which does not comply with a recommendation of use, incrementing a number of incidents by one unit, the electrical connector (130) then having to be revised if the number of incidents is greater than or equal to a maximum number of incidents;

• means (145), embedded on the unit (150), for transmitting an alert message to the manufacturer and to an operator of the electrical connector (130) when the electrical connector (130) must be overhauled.

Test bench for an electrical appliance comprising an electrical cabinet and an electrical connector (130) intended to electrically connect the electrical appliance (110) with the electrical cabinet (120), said bench further comprising a device (140) for monitoring the wear and behavior of the electrical connector (130) according to claim 6. Computer program comprising instructions adapted for the execution of the steps of the method according to one of Claims 1 to 5, when the computer program is executed by at least one processor. Recording medium readable by a computer or a mobile communication device on which is recorded a computer program comprising instructions for the execution of the steps of the method according to one of Claims 1 to 5.