FR3124003A1 - Method for studying the state of equipment, in particular equipment of a vehicle powertrain - Google Patents

Abstract

Method for studying the state of an item of equipment (2), the method comprising the following steps: - retrieving information relating to the evolution of at least one parameter during the use of a first item of equipment (2 ), - recording this information in a server (8), and - applying to a second equipment (10) instructions on the basis of the information thus recorded, in particular so that the behavior of the second equipment (10) reproduces that of the first equipment (2). Abstract Figure: Fig 1

Description

Method for studying the state of equipment, in particular equipment of a vehicle powertrain

The present invention relates to a method for studying the state of equipment, in particular equipment of a vehicle powertrain such as an electric propulsion machine, an actuator, a double clutch or a single clutch or another voltage converter.

It is known, to carry out predictive maintenance of equipment, to recover one or more operating parameters of this equipment and to have them analyzed by an external intelligence. It can thus be determined whether a repair or change of this equipment is desirable to prevent it from deteriorating.

Applications FR 2 605 170 and FR 2 676 556 disclose such predictive maintenance methods.

The known predictive maintenance methods do not make it possible to reproduce the behavior of the equipment whose predictive maintenance is to be carried out with sufficient precision.

There is a need to remedy this drawback. The object of the invention, according to one of its aspects, is to meet this need and it achieves this by means of a method for studying the state of equipment, the method comprising the following steps :

- retrieve information relating to the evolution of at least one parameter during the use of a first piece of equipment,

- save this information in a server, and

- apply instructions to a second piece of equipment on the basis of the information thus recorded, in particular so that the behavior of the second piece of equipment reproduces that of the first piece of equipment.

The invention can thus allow the behavior of the second equipment to be an image of the behavior of the first equipment. The first equipment is for example in the possession of the user while the second equipment is located on the premises of the manufacturer of the first equipment. Thus, this manufacturer can reproduce in its premises or elsewhere the behavior of the first equipment via the second equipment.

The method may comprise the step according to which the state in which the first equipment is located is deduced from the state of the second equipment. This deduction is preferably done via computer processing but can in some cases be done via visual inspection by a user. According to one aspect of the invention, it is therefore the second piece of equipment that is studied and not the first piece of equipment, and the conclusions drawn from the study of the second piece of equipment are considered to be valid for the first piece of equipment as well.

The process can thus make it possible to carry out predictive maintenance, since the state of wear of the second equipment makes it possible: to deduce the state of wear of the first equipment, and to estimate the risks of future degradation of the first equipment. The method can alternatively allow, in the event of failure or degradation of the first equipment, to benefit for the manufacturer from the presence of the second equipment whose behavior reproduces that of the first equipment. This avoids having to send the first piece of equipment back to the manufacturer, which can save time and reduce the effort required to identify the causes of this failure or degradation.

As a variant, the application to the second equipment of instructions generated on the basis of the information recorded from the first equipment is not intended to deduce the state of the first equipment but to study the behavior of the second equipment when it is subjected to the same constraints as the first equipment. It is thus possible to benefit from the behavior of the first equipment to develop or validate the second equipment.

In all of the above, the retrieval of information relating to the evolution of the parameter during use of the vehicle can be carried out via a wireless communication network, for example via a 3G, 4G or 5G network. When the equipment is integrated into a vehicle, this information retrieval can be carried out while the vehicle is in motion, or partly while the vehicle is in motion. The vehicle has, for example, a communication interface module that sends this information over the communication network.

In all of the above, the server can be a single server, for example located at the manufacturer of the first equipment, or implement several distributed servers. The recovery of data and their recording can be done via cloud computing.

The second equipment can be a virtual model of the first equipment. The second piece of equipment is thus a model produced via a computer system of the first piece of equipment and the instructions are entered into this computer system so as to reproduce the behavior of the first piece of equipment. This computer system uses, for example, Matlab®, Octave® or Mathematica®.

Alternatively, the second equipment is a physical model of the first equipment. This model corresponds for example to a physical object (“hardware”) operating according to the same principles as the first piece of equipment. The second equipment corresponds for example to a prototype used during the development of the first equipment.

As a further variant, the second device is a copy of the first device. The first and the second equipment are for example two parts differing only by their serial number. In the latter case, the method can make it possible to have a quasi identity between the state of the second equipment and that of the first equipment.

When the second equipment is a physical model of the first equipment or a copy of this first equipment, the second equipment can be placed on a test bench, so as to be able to best reproduce the conditions of use of the first equipment.

The parameter linked to the use of the first equipment can be at least one of: an equipment supply current, an equipment supply voltage, an equipment rotation speed or a torque engine exerted by the equipment or any other parameter. This may be the number of openings or closings when the first piece of equipment is a valve, in particular for a vehicle powertrain. All or part of these parameters are for example transmitted to the server. The setpoints applied to the second device can ensure that the latter also presents the same values for this or these output parameters. As a variant, the setpoints applied to the second equipment can consist of the direct application of these values for this or these parameters. ]

During the step in which the information relating to the evolution of the parameter during the use of the first equipment is recovered, it is also possible to recover information related to the climatic environment in which the first equipment operates. It is possible, if necessary, to generate additional instructions so that the second equipment operates in this same climatic environment.

This consideration of the climatic environment in which the first equipment operates can make it possible to bring the behavior of the second equipment even closer to that of the first equipment. This generation of additional instructions can be done just as well when the second equipment is a virtual model, a physical model or a copy of the first equipment. The information related to the climatic environment in which the first equipment operates includes, for example, at least one of: the temperature, the pressure, the hygrometry and the salinity in the air, or any other information.

This or this information related to the climatic environment in which the first equipment operates can be measured via sensors. As a variant, all or part of this information relating to the climatic environment of the first equipment can be obtained via numerical estimators, the latter using for example as input values data not referring to the climatic environment and deducing to using a pre-established map or any other means, such as a neural network, information relating to the climatic environment of the first equipment.

In all the above, the retrieval of information relating to the evolution of the parameter can be carried out continuously. Thus, the server is continuously supplied with information relating to the evolution of the parameter during the use of the first device. As already mentioned, the first piece of equipment can be integrated into a vehicle, in which case the server retrieves this information from a communication interface module of the vehicle.

As a variant, the recovery of information relating to the evolution of the parameter can be carried out on an ad hoc basis. This recovery can occur on a fixed or random periodicity. This recovery can also occur when a predefined condition is verified, for example stopping or starting the vehicle when the first equipment is integrated into this vehicle.

In all the above, the evolution of the parameter can take place during a given time sequence, and the setpoints for the second device can be generated in such a way as to respect this given time sequence. The use of the second device thus respects the cycles of use of the first device, allowing the behavior of the second device to be even closer to that of the first device. Thus, the periods of use of the second equipment can correspond to those of the first equipment, by their duration and/or by the time interval between two successive periods of use, for example. When the use of the second equipment respects the temporal sequence, this use can however be made in a manner offset with respect to that of the first equipment, for example only at night to avoid noise or other nuisances for the people near the second equipment.

As a variant, although the evolution of the parameter during the use of the first equipment takes place during a given time sequence, the generation of the instructions for the second equipment does not take this time sequence into account, so that the behavior of the second device does not respect this time sequence. Thus, the instructions applied to the second equipment may correspond to a range of use of the second equipment that is longer or shorter than according to the time sequence and/or the time interval between two successive ranges of use of the first equipment will not correspond to the time interval between two successive ranges of use of the second equipment.

In all of the foregoing, the first piece of equipment may be on board a vehicle, or be suitable for being on board a vehicle.

Within the meaning of the present application, the term “vehicle” designates any form of mobility with purely electric, hybrid, thermal or other propulsion. “Vehicle” thus encompasses a machine rolling on land via four, three, two wheels or any other number of wheels, or a machine moving in the air or on water, or even in space. An example of a vehicle is an automobile.

In such a case, the first piece of equipment may belong to the powertrain of the vehicle being for example an electrical machine for propelling the vehicle, or a voltage converter or an actuator or a single or double clutch.

When the first piece of equipment is an electric vehicle propulsion machine, it may be a machine whose shaft is integral in rotation:

- a gearbox input shaft, or

- of the gearbox output shaft, or

- gearbox idler gears, or

- the front axle or the rear axle of the vehicle.

As a variant, the shaft of the electric machine can be integral in rotation with the

crankshaft of the heat engine of the vehicle, when the powertrain includes such a heat engine. In such a case, the rotating electrical machine may comprise a pulley or any other means of connection to the rest of the vehicle's powertrain. The electric machine is for example connected, in particular via a belt, to the crankshaft of the heat engine of the vehicle.

This rotating electrical machine may have a nominal supply voltage of 12V, 48V, or more, for example a nominal voltage value greater than 200V, for example greater than 300V. As a further variant, this nominal supply voltage may be less than 12V.

If the first piece of equipment is a voltage converter, it may be an inverter/rectifier supplying a propulsion machine of the vehicle or a DC/DC voltage converter of the on-board network.

Other applications are possible within a vehicle powertrain, for example when the first piece of equipment is a battery.

As a variant, the invention can also be applied in other fields, for example in computing or communication or even in household appliances.

Another subject of the invention, according to another of its aspects, is a system for implementing the method described above, this system comprising:

- means for recovering information relating to the evolution of at least one parameter during the use of a first piece of equipment,

- a server to record this information, and

-means for applying instructions to a second piece of equipment on the basis of the information thus recorded, in particular so that the behavior of the second piece of equipment reproduces that of the first piece of equipment.

All or part of what has been mentioned in connection with the process still applies to the above system.

The invention can be better understood on reading the following description of non-limiting examples thereof and on examining the attached drawing in which:

- schematically represents an environment within which part of the method according to one embodiment of the invention is implemented, and

- schematically represents an environment within which another part of the method is implemented according to the embodiment of the .

We represented on the an environment 1 within which part of a method according to one embodiment of the invention can be implemented. This embodiment consists in studying the state of a first device using a second device.

In the example of the , the first piece of equipment 2 is a machine for propelling a vehicle powertrain. The vehicle here is an automobile but other applications are possible. The propulsion machine allows the propulsion of an electric or hybrid vehicle, having in the example considered a nominal voltage of 48V or other, for example a voltage whose value is greater than 200V, in particular 300V, being for example less than 800V.

When the vehicle is running, the information relating to the evolution of one or more parameters related to this running is transmitted via a communication interface module 4 to a wireless communication network 5. This network 5 puts for example implements 3G, or 4G or 5G technology. Several parameters are for example studied, such as the speed of rotation of the first device 2, its supply voltage, its supply current or even the motor torque supplied.

In the example considered, the communication interface module 4 also collects information related to the climatic environment in which the first equipment 2 operates. This information comprises for example at least one of: the temperature, the pressure and the hygrometry of the environment in which the first equipment 2 operates. This information can be obtained via sensors or via digital estimators 6. Alternatively, this information can be obtained on the network 5 other than from the vehicle, for example by cooperation with access or content providers.

The network 5 allows the transmission of this information to a server which is for example produced via a decentralized computer 8. It is thus possible to record in this server 8 the information retrieved in relation to the use of the first equipment 1. If necessary, these information can be supplemented by information representing the source of electrical energy supplying this first equipment 2

This transmission of information can be done continuously, the information being transmitted to the server 8 permanently, or at least when the vehicle is running or at least when the ignition is on.

Alternatively, this transmission of information is only done on an ad hoc basis. This transmission is done for example only according to a fixed or variable periodicity, depending for example on the age of the first equipment 2 and/or on its number of hours of use and/or on the detection of the end of a journey .

The information thus recovered and recorded is transmitted by the network 5 to a second device 10 visible at the . This second equipment 10 is in the example considered a copy of the first equipment 2, differing from this first equipment 2 only by its serial number. In variants not shown, the second equipment can be a virtual model, produced via a computer system, of the first equipment 2 or a physical model of this first equipment 2, for example a prototype of this first equipment 2.

In the example considered, the second equipment 10 is mounted on a test bench and in an enclosure 11 in which the climatic conditions are modifiable. Of course, the invention also applies when the possibility of modifying the climatic conditions for the second equipment item 10 does not exist.

The recovery of the information recorded in the server 8 is done in the example described via a computer 12, but any equivalent computer system such as a tablet is valid. This computer 12 is here configured to generate, on the basis of the information received from the server 8, instructions to be applied to the second equipment 10 so that its behavior reproduces that of the first equipment 2. The computer 12 also generates in the example describes additional instructions allowing control devices 13 and 14 of the enclosure 11 to best reproduce the climatic conditions in which the first piece of equipment 2 was operating when the information relating to the evolution of the parameters was recorded on the basis which the instructions are generated by the computer 12. In the example represented, the device 13 makes it possible to adjust the temperature in the enclosure 11 and the device 14 makes it possible to adjust the humidity in this enclosure 11.

In the case where the parameters studied for the first piece of equipment 2 are the supply current of the electric machine and its speed of rotation, for example, the instructions applied by the computer 12 to the second piece of equipment 10 are for example generated so as to that the supply current of the electric machine and/or its speed of rotation are as close as possible, for example identical, to those related to the first equipment item 2.

The embodiment of the invention described thus makes it possible, via the second equipment 10, to have an image, in particular as faithful as possible, of the first equipment 2. Thus, a diagnosis as to the state of the first equipment 2 can be carried out remotely, and this diagnosis can make it possible to decide on a predictive maintenance operation of the first equipment 2 or to understand the reasons for a breakdown or degradation of the first equipment 2.

The information relating to the evolution of the parameter for the first equipment 2 can correspond to a given time sequence, and the generation of the instructions by the computer 12 can be done in such a way that this time sequence is respected by the second equipment 10 Thus, if the evolution of the parameter has been observed during a given duration for the first equipment 2, the application of the instructions to the second equipment 10 can correspond to the same duration for the evolution of the parameter for the second equipment 10 .

The invention is not limited to the example which has just been described.

Claims (13)

Method for studying the state of an item of equipment (2), the method comprising the following steps:
- recover information relating to the evolution of at least one parameter during the use of a first device (2),
- save this information in a server (8), and
- apply instructions to a second device (10) on the basis of the information thus recorded, in particular so that the behavior of the second device (10) reproduces that of the first device (2). Method according to claim 1, wherein the second equipment (10) is a virtual model of the first equipment (2). Method according to claim 1, in which the second equipment (10) is a physical model of the first equipment (2). Method according to claim 1, wherein the second equipment (10) is a copy of the first equipment (2). A method according to any preceding claim, wherein the parameter is at least one of: an equipment supply current, an equipment supply voltage, an equipment rotation speed or a motor torque exerted by the equipment. Method according to any one of the preceding claims, in which during the step in which the information relating to the evolution of the parameter during the use of the first equipment (2) is recovered, information related to the climatic environment in which the first equipment (2) evolves, and in which additional instructions are generated so that the second equipment (10) evolves in this same climatic environment Method according to claim 6, in which the information related to the climatic environment in which the first equipment item (2) operates comprises at least one of: the temperature, the pressure and the hygrometry. Method according to any one of the preceding claims, in which the step of recovering information relating to the evolution of the parameter is carried out continuously. Method according to any one of Claims 1 to 7, in which the step of recovering information relating to the evolution of the parameter is carried out on an ad hoc basis, in particular according to a fixed or random periodicity. Method according to any one of the preceding claims, in which the evolution of the parameter takes place during a given time sequence, and in which the setpoints for the second equipment (10) are generated so as to respect this given time sequence. Method according to any one of the preceding claims, in which the first equipment item is on board or capable of being on board a vehicle. Method according to claim 11, in which the equipment belongs to the powertrain of a vehicle being for example an electrical machine for propelling the vehicle, or a voltage converter or an actuator or a single or double clutch. System for implementing the method according to any one of the preceding claims, this system comprising:
- means for recovering information relating to the evolution of at least one parameter during the use of a first device (2),
- a server (8) for recording this information, and
- means (12) for applying to a second equipment (10) instructions on the basis of the information thus recorded, in particular so that the behavior of the second equipment (10) reproduces that of the first equipment (2).