WO2022269145A1

WO2022269145A1 - Management of a voltage converter control unit for a motor vehicle

Info

Publication number: WO2022269145A1
Application number: PCT/FR2022/050731
Authority: WO
Inventors: Olivier BALENGHIEN; Marc POTIER
Original assignee: Psa Automobiles Sa
Priority date: 2021-06-22
Filing date: 2022-04-19
Publication date: 2022-12-29
Also published as: FR3124129A1; EP4359249A1

Abstract

The invention relates to a method for operating a voltage converter control unit (4) enabling control of the charging of a high-voltage battery (3) of an electrified motor vehicle (1). Such an operating method involves a step of verifying that various computers of the electrified motor vehicle (1) are in an awakened condition so as to activate electrical polarisation thereof by the high-voltage electric battery (3) in the status wherein charging is complete and the level of charge is sufficient, and prevent operation thereof if that status is not achieved.

Description

DESCRIPTION

TITLE OF THE INVENTION: MANAGEMENT OF A VOLTAGE CONVERTER CONTROL UNIT FOR A MOTOR VEHICLE

[1] |The present invention claims the priority of French application N°2106599 filed on 06.22.2021, the content of which (text, drawings and claims) is incorporated herein by reference.

[2] The technical context of the present invention is that of the electrical management of a motor vehicle of the electric or hybrid type. More particularly, the invention relates to the energy management of several computers of the motor vehicle during or following the electric charging of said motor vehicle via a charging station. In particular, the invention relates to a method for controlling the control unit of a voltage converter.

[3] In known manner, it is possible to recharge the high voltage electric battery of an electrified motor vehicle by a charging station, which thus makes it possible to electrically couple the high voltage electric battery to an urban electricity supply network or private, in order to transfer electrical energy from the electrical supply network to the high-voltage electrical battery.

[4] The electric charge of the high voltage electric battery is supervised by the voltage converter control unit which makes it possible to electrically adapt the electric power supply network to a high voltage electric network of the electrified motor vehicle.

[5] In known manner, when the charging of the high voltage electric battery is complete, the high voltage electric battery having a completed state of charge and a maximum level of charge, if the high voltage electric battery is maintained electrically coupled to the terminal charging station, it has been noted, on certain charging stations, that the charging station could at times request the electrified motor vehicle and wake up> a certain number of computers of the electrified motor vehicle, after the electric battery has been fully charged, thus leading to a current draw from a low voltage service electric battery and to unwanted electrical consumption. Consecutively, and quite undesirably, it was found that despite the charging of the high voltage electric battery carried out by the charging station, the computers used discharged the service electric battery after it was charged, so that the user of the electrified motor vehicle, although having left his vehicle charged for several hours, even several days, would resume it with a partially discharged, or even completely discharged service electric battery.

[6] The object of the present invention is to propose a new piloting method in order to respond at least in large part to the previous problems and to also lead to other advantages.

[7] Another object of the invention is to improve the reliability of the safety electric charging of an electrified motor vehicle.

[8] Another object of the invention is to optimize the management of the high voltage electric battery of such an electrified motor vehicle.

[9] According to a first aspect of the invention, at least one of the aforementioned objectives is achieved with a method for controlling a control unit of a voltage converter for an electrified motor vehicle, the control method comprising a step of prohibiting the awakening of computers of the electrified motor vehicle, the step of prohibiting awakening being implemented by the control unit of the voltage converter, if the following non-waking conditions are cumulatively verified:

[10] - a high voltage electric battery of the electrified motor vehicle has a complete state of charge; and

[11] - a charge level of the high voltage electric battery is greater than or equal to a threshold level.

[12] In the context of the invention, the voltage converter control unit is known as OBCDC. It involves :

[13] - a first part configured to allow the charging of the high voltage electric battery, in particular ensuring communication with charging terminals and monitoring the electric charging of the high voltage electric battery; and [14] - a second part taking the form of a DC/DC converter making it possible to convert an electric current conveyed to the high voltage electric battery.

[15] During electrical recharging of the motor vehicle, the DC/DC voltage converter converts the 220V alternating current into direct current towards the high voltage electric battery. When the motor vehicle is moving, the DC/DC converter converts part of the current from the high voltage electric battery to supply the on-board network of the motor vehicle in order to recharge a low voltage electric battery of the motor vehicle.

[16] The high voltage electric battery is the traction battery of the electrified motor vehicle. By way of non-limiting example, the high-voltage electric battery is of the type of a lithium-ion battery.

[17] The service electric battery, known as low voltage, is the electric battery that powers a low voltage electrical network of the electrified motor vehicle. It is in particular this electric service battery which is electrically connected to the computers, control units and, in general, to the various electrical components of the electrified motor vehicle in order to polarize them to allow their correct operation.

[18] In the context of the invention, the charge level and the threshold level of the high-voltage electric battery are understood as a relative value with respect to a maximum level of charge of the electric battery for which said high-voltage electric battery voltage is fully charged and thus stores maximum electrical energy compared to storage capacities of the high voltage electrical battery. The charge level and the threshold level of the high voltage electric battery are set in percentage. When the high voltage electric battery is fully charged, then its charge level is 100%. When the high voltage electric battery is fully discharged, its charge level is at 0%.

[19] The computers subject to the wake-up ban controlled by the converter control unit are the computers of the electrified motor vehicle which are linked to the voltage converter control unit. More particularly, by "linked", it is understood that it is the computers of the electrified self-propelled vehicle which intervene when recharging the high voltage electric battery.

[20] The computers linked to the voltage converter control unit include a BSI - acronym for Intelligent Service Box, and/or a powertrain supervision unit and/or a high electric battery supervision computer tension. In general, the computers linked to the voltage converter control unit are those implemented for or via the control of the high voltage electric battery. As mentioned above, these electrical components are electrically connected to the electric service battery in order to be able to operate.

[21] In general, the computers are woken up by the voltage converter control unit if the waking conditions are verified. In other words again, the voltage converter control unit is authorized to wake up the computers linked to it if the wake-up conditions are verified.

[22] By alarm clock, it is understood that the voltage converter control unit controls a power supply in such a way that the computers are polarized - for example via the electric service battery - and become active, i.e. functional. In other words, when the voltage converter control unit is authorized to wake up the ECUs, then the electric service battery is authorized to polarize them electrically so that they can operate. To this end, the voltage converter control unit controls the electric service battery so as to allow it to achieve such polarization, for example by controlling a switch which makes it possible to electrically couple the electric service battery to the aforementioned computers.

[23] By way of non-limiting example, a computer is woken up if it sends data to a communication network or to other computers or to the voltage converter control unit.

[24] Conversely, when the computers are not electrically polarized so that they can be functional, then their state is said to be asleep. By asleep or falling asleep, it is understood that the control unit of the voltage converter drives a power supply in such a way that the computers are not polarized - for example via the electric service battery - and become inactive, that is to say non-functional. In other words, when the voltage converter control unit is prohibited from waking up the computers, then the electric service battery is not authorized to polarize them electrically. To this end, the voltage converter control unit controls the electrical service battery so as to prevent their electrical polarization, for example by controlling a switch which makes it possible to electrically decouple the electrical service battery from the aforementioned computers.

[25] By wake-up authorization, it is understood that, if such authorization is granted to the voltage converter control unit, said voltage converter control unit is configured to be able - in the wake of the authorization or subsequently - allow the computers to be electrically polarized by the electric service battery in order to operate. In the context of the invention, it is indeed the voltage converter control unit which verifies the conditions in order to be able itself - in the wake of the wake-up authorization or subsequently - to electrically bias the computers in order to operate .

[26] Conversely, by waking up prohibition, it is understood that, if the voltage converter control unit is configured with such a prohibition, then said voltage converter control unit is configured to be able - in the wake of prohibition or later - prevent the computers from being electrically polarized by the electric service battery. In the context of the invention, it is indeed the voltage converter control unit which verifies the conditions in order to be able itself - in the wake of the wake-up ban or subsequently - to electrically decouple the computers from the battery utility power to prevent them from working.

[27] In the context of the invention, the control method in accordance with the first aspect of the invention is more particularly implemented when charging the high voltage electric battery of the electrified motor vehicle by a charging station, or subsequently thereto, and even more particularly when the charging terminal is still electrically coupled to the control unit of the voltage converter. [28] The control method in accordance with the first aspect of the invention is implemented on or for an electric or hybrid motor vehicle, such motor vehicles comprising a high voltage electric battery, called a traction battery, configured to allow powering electrically at least one electric motor used to move said motor vehicles.

[29] The piloting method in accordance with the first aspect of the invention advantageously comprises at least one of the improvements below, the technical characteristics forming these improvements being able to be taken alone or in combination:

[30] - the threshold level of the high voltage electric battery is equal to 92%;

[31] - the waking up prohibition is granted to the voltage converter control unit if the following additional non-waking up condition is verified: an electrical voltage taken from the terminals of a low voltage network of the electrified motor vehicle is less than or equal to a threshold voltage;

[32] - the threshold voltage of the low voltage network is equal to 12.3 V. In general, the threshold voltage of the low voltage network is predetermined according to a value defined in the factory or according to initialization parameters of the process of piloting according to the invention;

[33] - no-wake-up permission is granted to the voltage converter control unit if no-wake-up conditions are verified for a predetermined integration time. By way of non-limiting example, the integration time is between 10 seconds and 60 seconds. Preferably, the integration time is equal to 30 seconds;

[34] - the step of prohibiting the waking up of the computers by the voltage converter control unit comprises a step of setting a non-waking up authorization variable during which the wake-up is configured in a so-called inactive state for which the voltage converter control unit is configured not to wake up the computers. In other words, when the wake-up authorization variable is in its inactive state, the control unit of the voltage converter controls a low-voltage electrical network of the electrified motor vehicle and/or the electrical service battery of way to electrically decouple the computers in order to make them non-functional;

[35] - during the step for setting the wake-up authorization variable, the wake-up authorization variable is configured in a so-called active state for which the voltage converter control unit is configured to be able to wake up the computers if at least one of the following wake-up conditions is fulfilled: (i) if the voltage converter control unit and a charging station of the high-voltage electric battery are electrically decoupled, or (ii) if the computers are waked up . In other words, when the wake-up authorization variable is in its active state, the voltage converter control unit is authorized to electrically polarize the computers in order to make them functional: the computers are functional when the variable d wake-up authorization is in its active state. In other words, they are electrically polarized by the electric service battery;

[36] - the wake-up authorization variable is advantageously a Boolean variable that can take either the active state associated with a first Boolean value, or the inactive state associated with a second Boolean value different from the first Boolean value;

[37] - the control process includes a step of recording the wake-up authorization variable in a memory of the voltage converter control unit.

[38] According to a second aspect, the subject of the invention is a control unit for a voltage converter of a high-voltage electric battery of an electrified motor vehicle, the control unit being configured to implement the method of piloting in accordance with the first aspect of the invention or according to any one of its improvements.

[39] According to a third aspect, the invention also extends to an electrified motor vehicle comprising:

[40] - a powertrain comprising a high voltage electric battery, called traction, a voltage converter configured to be able to recharge the high voltage electric battery from a charging station electrical via an electrical power supply network and/or from regenerative braking of the electrified motor vehicle;

[41] - a voltage converter control unit according to the second aspect of the invention, the voltage converter control unit being electrically coupled to the voltage converter in order to control a charge of the high voltage electric battery.

[42] Advantageously, the electrified motor vehicle is of the type of an electric or hybrid vehicle, the rechargeable high voltage electric battery being of the type of a high voltage electric battery configured to supply high voltage electric power to a traction chain of the vehicle automobile.

[43] Various embodiments of the invention are provided, integrating, according to all of their possible combinations, the various optional features set out here.

[44] Other characteristics and advantages of the invention will become apparent through the description which follows on the one hand, and the examples of embodiment given by way of indication and not limitation with reference to the appended diagrammatic drawings on the other hand, on which ones :

[45] [Fig.1] schematically illustrates a motor vehicle according to the third aspect of the invention;

[46] [Fig.2] illustrates a synoptic view of the control method according to the first aspect of the invention.

[47] Of course, the features, variants and different embodiments of the invention may be associated with each other, in various combinations, insofar as they are not mutually exclusive or mutually exclusive. In particular, variants of the invention may be imagined comprising only a selection of characteristics described below in isolation from the other characteristics described, if this selection of characteristics is sufficient to confer a technical advantage or to differentiate the invention from to the state of the prior art. [48] In particular, all the variants and all the embodiments described can be combined with each other if nothing prevents this combination from a technical point of view.

[49] In the figures, the elements common to several figures retain the same reference.

[50] The invention applies to electrified vehicles, in particular plug-in, hybrid and electric motor vehicles.

[51] FIGURE 1 illustrates an embodiment of an electrified motor vehicle 1 electrified capable of implementing the steering method 9 according to the invention. The electrified motor vehicle 1 comprises a powertrain provided with a powertrain supervision unit 2, an electric traction machine (not shown) powered by a high voltage electric battery 3 - called traction - and a control unit of a DC/DC direct current converter 4 forming a device for recharging the high voltage electric battery 3.

[52] The high voltage electric battery 3 generally provides several hundred volts, for example 450V, in order to ensure the supply of electric energy to a traction chain of the electrified motor vehicle 1. The high voltage electric battery 3 comprises several electric cells, for example of the Lithium-ion type. The high voltage electric battery 3 collaborates with a high voltage battery management computer.

[53] The voltage converter control unit 4 comprises:

[54] - charging means cooperating with a power outlet 6 so as to be able to electrically connect an external charging terminal 7 connected to a power supply network 8. As such, the control unit of the voltage converter 4 is in charge of managing communication between different types of charging stations and monitoring and controlling electric charging on one of them; and

[55] - an alternating/direct AC/DC and direct/direct DC/DC electrical converter. A first function is to convert an alternating voltage delivered by the charging terminal 7 into a direct voltage compatible with the high voltage electric battery 3. A second function is to convert electric voltages for supplying an electric service battery (12V) and on-board systems of the electrified motor vehicle 1 such as for example the low voltage on-board network - approximately 14V - and for the electric traction machine, when driving and when braking recuperative.

[56] The voltage converter control unit 4 communicates with various computers of the motor vehicle, and in particular with the powertrain group supervision unit 2 via a communication network 5 on which the powertrain group supervision unit powertrain 2 transmits environmental data from the electrified motor vehicle 1.

[57] According to the invention, the voltage converter control unit 4 is equipped with an integrated circuit computer and electronic memories. The voltage converter control unit 4 according to the second aspect of the invention is configured to implement the triggering method according to the first aspect of the invention

[58] The computer can be external to the voltage converter control unit 4, while being coupled to the latter. In the latter case, it can itself be arranged in the form of a dedicated computer comprising for example a possible dedicated program. Consequently, the control unit, according to the invention, can be produced in the form of software or computer modules, or else of electronic circuits, or even of a combination of electronic circuits and software modules.

[59] FIGURE 2 illustrates an exemplary embodiment of the method 9 for controlling a control unit of the voltage converter 4 for an electrified motor vehicle 1, the control method 9 comprising a step 95 for prohibiting the waking up of the computers of the electrified motor vehicle 1 linked to the control unit of the voltage converter 4 if non-awakening conditions are cumulatively verified among the following:

[60] - a first wake-up condition 91 in which the high-voltage electric battery 3 has a finished state of charge; and

[61] - a second wake-up condition 92 in which a charge level of the high voltage electric battery 3 is greater than or equal to a threshold level. [62] Within the meaning of the invention, the computers which are awake, that is to say electrically polarized so as to be able to be activated and/or transmit data on the communication network 5 of the electrified motor vehicle 1 include those which are directly or indirectly linked to the powertrain of the electrified motor vehicle, such as for example a BSI - acronym for Intelligent Servitude Box, a powertrain supervision unit or a supervision computer for the high voltage electric battery.

[63] Within the meaning of the invention, the computers which are asleep or not awake, that is to say electrically decoupled from the electric service battery so as not to be able to be activated and/or transmit data on the communication network 5 of the electrified motor vehicle 1 include those which are linked directly or indirectly to the powertrain of the electrified motor vehicle, such as for example a BSI - acronym for Intelligent Servitude Box, a powertrain supervision unit or a computer supervision of the high voltage electric battery.

[64] Optionally, a third additional non-wake-up condition 93 is taken into account, cumulatively with the two previous ones, to provide the wake-up prohibition to the control unit of the voltage converter 4: an electrical voltage taken from the terminals of a low voltage network of the electrified motor vehicle 1 is less than or equal to a threshold voltage.

[65] The voltage converter control unit 4 tests these non-awakening conditions during a comparison step 94 carried out according to a given comparison frequency.

[66] Of course, in the context of the invention, the threshold level of the high voltage electric battery 3 and the threshold voltage of the low voltage network beyond which the prohibition for the control unit of the converter of voltage 4 to wake up the computers of the electrified motor vehicle is granted are predetermined and/or configurable. By way of non-limiting examples, the threshold voltage of the low voltage network is equal to 12.3 V, and/or the threshold level of the high voltage electric battery is equal to 92%.

[67] Advantageously, the voltage converter control unit 4 tests the verification of these non-awakening conditions during an integration period predetermined in order to avoid taking into account an aberrant value. By way of non-limiting example, the integration period is less than one minute, preferably equal to 30 seconds.

[68] In a particularly advantageous manner, for the implementation of the control method 9 according to the invention, the step of prohibiting the waking up of the computers by the control unit of the voltage converter 4 includes a setting step 96 a wake-up authorization variable during which the wake-up authorization variable is configured:

[69] - in a so-called inactive state if the non-awakening conditions are verified, the voltage converter control unit 4 then being configured to allow electrical decoupling of the computers from the electric service battery in order to put them to sleep and /or to control the electric service battery so as not to electrically polarize said computers; Where

[70] - in a so-called active state for which the voltage converter control unit is configured to be able to wake up the computers if at least one of the following wake-up conditions is fulfilled: (i) if the converter control unit of voltage and a charging station of the high voltage electric battery are electrically decoupled, or (ii) if the computers are awake.

[71] The control method 9 also includes a step 97 of recording the wake-up authorization variable on a memory of the control unit of the voltage converter 4.

[72] In summary, the invention relates to a method for controlling a control unit of a voltage converter 4 making it possible to control the charge of a high voltage battery 3 of an electrified motor vehicle 1. Such a method control includes a step for checking the wake-up conditions of several computers of the electrified motor vehicle 1 in order to activate their electric polarization by the low-voltage electric battery in the event of an incomplete state of charge and an insufficient level of charge, and to prevent them from functioning otherwise.

[73] Of course, the invention is not limited to the examples which have just been described and many adjustments can be made to these examples without departing from the scope of the invention. In particular, the different characteristics and variants implementation of the invention can be associated with each other in various combinations insofar as they are not incompatible or exclusive of each other. In particular, all the variants and embodiments described above can be combined with each other. I

Claims

[Claim 1] ÎControl method (9) of a control unit of a voltage converter (4) for an electrified motor vehicle (1), the control method comprising a step of prohibiting the awakening (95) of computers of the electrified motor vehicle (1), the wake-up prohibition step (95) being implemented by the control unit of the voltage converter (4), if non-wake-up conditions (91, 92, 93 ) are cumulatively verified:

- a high-voltage electric battery (3) of the electrified motor vehicle (1) has a completed state of charge; and

- a charge level of the high voltage electric battery (3) is greater than or equal to a threshold level.

[Claim 2] Control method (9) according to the preceding claim, in which the threshold level of the high-voltage electric battery (3) is equal to 92%.

[Claim 3] Control method (9) according to any one of the preceding claims, in which the wake-up prohibition is granted to the control unit of the voltage converter (4) if the no-wake-up condition (91 , 92, 93) following additional is verified:

- an electrical voltage taken at the terminals of a low voltage network of the electrified motor vehicle (1) is less than or equal to a threshold voltage.

[Claim 4] Control method (9) according to the preceding claim, in which the threshold voltage of the low-voltage network is equal to 12.3 V.

[Claim 5] Control method (9) according to any one of the preceding claims, in which the wake-up prohibition is granted to the control unit of the voltage converter (4) if the non-wake-up conditions are verified. for a predetermined integration time.

[Claim 6] Control method (9) according to any one of the preceding claims, in which the step of prohibiting wake-up (95) of the computers by the control unit of the voltage converter (4) comprises a step setting (96) a wake-up authorization variable in which the wake-up authorization variable is configured in a so-called inactive state for which the voltage converter control unit (4) is configured not to wake up the computers.

[Claim 7] Control method (9) according to the preceding claim, in which, during the step of setting (96) the wake-up authorization variable, the wake-up authorization variable is configured in a so-called active state for which the voltage converter control unit (4) is configured to be able to wake up the computers if at least one of the following wake-up conditions is fulfilled:

- if the voltage converter control unit (4) and a charging station for the high voltage electric battery (3) are electrically decoupled; Where

- if the computers are awake.

[Claim 8] Piloting method (9) according to any one of claims 6 or 7, in which the piloting method (9) comprises a step of recording the wake-up authorization variable on a memory of the voltage converter control unit (4).

[Claim 9] Control unit of a voltage converter (4) of a high voltage electric battery (3) of an electrified motor vehicle (1), the control unit of the voltage converter (4) being configured to put implements the control method (9) according to any one of the preceding claims.

[Claim 10] Electrified motor vehicle (1) comprising:

- a powertrain comprising a high voltage electric battery (3), called traction, a voltage converter configured to be able to recharge the high voltage electric battery (3) from an electric charging station (7) via a network power supply (8) and/or from regenerative braking of the electrified motor vehicle (1);

- a voltage converter control unit (4) according to the preceding claim, the voltage converter control unit (4) being electrically coupled to the voltage converter in order to control a charge of the high voltage electric battery (3) .|