WO2023222958A1

WO2023222958A1 - Device for controlling the power supply of an external connector temporarily coupled to a connector for recharging a system

Info

Publication number: WO2023222958A1
Application number: PCT/FR2023/050410
Authority: WO
Inventors: Benoit Seguin; Tetiana Salivon; Lisa GILLES; Jean-Francois Gautru
Original assignee: Stellantis Auto Sas
Priority date: 2022-05-20
Filing date: 2023-03-22
Publication date: 2023-11-23
Also published as: FR3135669A1

Abstract

The invention relates to a control device (DC) provided for a system (S) comprising a recharging connector (CR) temporarily coupled to an external connector (CE) having a detectable type, and comprising a control line (LC) connected to this recharging connector (CR) and enabling information to be exchanged with this external connector (CE). This device (DC) comprises a selection circuit (CS) which is installed on the control line (LC) and connected to a power supply circuit (C1) of the system (S), and which couples the recharging connector (CR) to the power supply circuit (C1) when the detected type is representative of a power supply requirement of at least one internal device (DIj) of the external connector (CE) which is able to be coupled to the control line (LC).

Description

DESCRIPTION

TITLE: DEVICE FOR CONTROLLING THE POWER SUPPLY OF AN EXTERNAL CONNECTOR TEMPORARILY COUPLED TO A CHARGING CONNECTOR OF A SYSTEM

The present invention claims the priority of French application No. 2204887 filed on 05.20.2022, the content of which (text, drawings and claims) is here incorporated by reference.

Technical field of the invention

The invention relates to systems comprising a charging connector that can be temporarily coupled to an external connector, and more specifically to controlling the power supply of such external connectors.

State of the art

Certain systems, such as for example certain vehicles (possibly of the automobile type), include a battery which is rechargeable under the control of an on-board charger, and a charging connector which is coupled to this battery and this charger and capable of being temporarily coupled to an external connector connected to an external power source during a recharging phase of this battery.

It has recently been proposed to use this type of system as an electrical power source for at least one external (electrical) device, such as for example an electric bicycle, a trailer, a caravan, a barbecue or a device. 'lighting. To do this, we connect the external (electrical) device to the charging connector of the system, via a power supply cable, and we supply the latter, via the charging connector, with electrical energy from the rechargeable battery of the system.

When we want this supply of electrical energy to be secure, it is essential that at least one dedicated electrical (or electronic) device, ensuring at least one function linked to this security, is present in the electrical supply chain. Therefore, this (each) dedicated electrical (or electronic) device can be installed in the external connector, the charging connector or between the charging connector and the on-board charger or rechargeable battery.

The installation of at least one such dedicated electrical (or electronic) device in a vehicle is advantageous because it allows a power supply of this dedicated electrical (or electronic) device with electrical energy stored in the vehicle. However, this increases the cost of the vehicle and requires introducing diversity into the vehicle when installation is optional. Installing at least one dedicated electrical (or electronic) device in an external connector avoids having to adapt vehicles. However, it requires a power supply for each dedicated electrical (or electronic) device, which, currently, is done by means of at least one rechargeable cell or battery housed in the external connector. This not only increases the size but also the cost of the external connector. In addition, this requires the user to carry out maintenance operations to replace the battery or recharge the battery. In addition, it may happen that the battery or rechargeable battery is discharged when the user wants to use the electrical power cable including the external connector, and if the user does not have a backup battery or a means to recharge the rechargeable battery it cannot use this power cable and therefore cannot electrically power at least one external device.

The invention therefore aims in particular to improve the situation.

Presentation of the invention

For this purpose, it proposes in particular a control device intended to equip a system comprising a charging connector capable of being temporarily coupled to an external connector having a detectable type, and a control line connected to this charging connector and allowing exchanges of information with this external connector.

This control device is characterized by the fact that it comprises a selection circuit adapted to be installed on the control line and to be connected to a power supply circuit of the system, and adapted to couple the connector charging to the electrical power supply circuit when the detected type is representative of a need for electrical power supply of at least one internal device of the external connector, capable of being coupled to the control line.

Thanks to the invention, the external connector no longer needs to include a rechargeable battery to power each of its internal devices, and therefore there is no longer any risk that the user will not be able to use it and its size is reduced, and if the option of powering the external connector is not provided in the system it can either not be equipped with a control device, or configure the latter so that it cannot only allow refills.

The control device according to the invention may include other characteristics which can be taken separately or in combination, and in particular:

- its selection circuit may be capable of coupling either the charging connector to the electrical power supply circuit via a first sub-part of the control line in the event of receipt of a first command generated by a computer following receipt of 'a first type information generated by a detection circuit equipping the system, connected to the charging connector and capable of detecting the type of the external connector, i.e. this first sub-part to a second sub-part of the control line in the event receiving a second command generated by this computer following receipt of a second type of information generated by this detection circuit;

- in the presence of the first option, it can include the calculator;

- its selection circuit may comprise a switch, on the one hand, having first and second terminals connected respectively to first and second sub-parts of the control line and a third terminal connected to the electrical supply circuit, and, on the other hand, suitable for coupling the first terminal to the second or third terminal depending on the type detected.

The invention also proposes a system, possibly of automobile type, and comprising, on the one hand, a charging connector capable of being temporarily coupled to an external connector having a detectable type, and a control line connected to this charging connector and allowing exchanges information with this external connector, and, on the other hand, an electrical supply circuit capable of supplying a chosen supply voltage, and a control device of the type of that presented above and connected to this circuit power supply.

For example, this system can also include a detection circuit connected to its charging connector and capable of detecting the type of the external connector.

The invention also proposes an external connector having a detectable type and capable of being connected to a charging connector equipping a system which comprises a control line connected to this charging connector and allowing exchanges of information with this external connector.

This external connector is characterized in that it comprises at least one internal device capable of ensuring at least one chosen internal function when it is powered by a chosen voltage supplied by the system via the charging connector on terminals associated with the line of control.

For example, each internal function can be chosen from a function for controlling the operation of at least part of the external connector, a function for monitoring at least part of the external connector, a function for protecting at least one part of the external connector. of the external connector, a function for diagnosing the operation of at least part of the external connector, and a function for signaling at least one operating state of an internal device.

Also for example, this external connector can constitute an adapter to which a cable capable of electrically supplying at least one external device can be temporarily connected.

The invention also proposes an electrical power cable capable of electrically supplying at least one external device and comprising an external connector of the type presented above.

Brief description of the figures

Other characteristics and advantages of the invention will appear on examination of the detailed description below, and the appended drawings, in which: [Fig. 1] schematically and functionally illustrates an exemplary embodiment of a vehicle comprising a GMP, with an electric motor powered by a rechargeable main battery and coupled to a charging connector, and a control device according to the invention, and

[Fig. 2] illustrates schematically and functionally an exemplary embodiment of an external connector forming part of an electrical power cable and temporarily connected to a charging connector of a vehicle comprising an exemplary embodiment of a control device according to 'invention.

Detailed description of the invention

The invention aims in particular to propose a DC control device intended to equip a system S comprising a charging connector CR coupled to a rechargeable battery BR and to which can be temporarily connected an external connector CE comprising at least one internal device Dlj in front be electrically powered by this system S via its CR charging connector on terminals associated with an LC control line.

In what follows, we consider, by way of non-limiting example, that the system S is a motor vehicle. This is for example a car, as illustrated in Figure 1. But the invention is not limited to this type of system. It concerns any type of system comprising a charging connector making it possible to recharge a rechargeable battery when an external connector, coupled to an external power source, is connected to it. Consequently, the system can be a vehicle (land, sea (or river), or air), an electrical appliance (including household or consumer appliances), an installation (including industrial type), or a building.

Furthermore, we consider in what follows, by way of non-limiting example, that the system S (here a vehicle) comprises a powertrain (or GMP) of all-electric type (and therefore whose traction is ensured exclusively by at least least one electric driving machine MME). But the GMP could be of hybrid type (thermal and electric). In addition, we consider in what follows, by way of non-limiting example, that the rechargeable battery BR of the system S, coupled to the charging connector CR, is responsible for powering the electric motive machine MME of the GMP, a battery of BS easement and an RB on-board network. This is therefore a main (or traction) battery. But the BR battery could provide electrical energy for only part of the aforementioned equipment and/or at least one other piece of equipment in its system S.

We have schematically represented in Figure 1 a system S (here a vehicle) comprising an electric GMP transmission chain (and therefore an MME electric driving machine), an on-board network RB, a service battery BS, a main battery ( or traction) BR, a CV converter, a CR charging connector, and a DC control device according to the invention.

The RB on-board network is an electrical supply network to which electrical (or electronic) equipment (or components) are coupled which consume electrical energy.

The utility battery BS is responsible for supplying electrical energy to the on-board network RB, in addition to that supplied by the CV converter powered by the main battery BR, and sometimes in place of this CV converter. For example, this BS utility battery can be arranged in the form of a very low voltage type battery (typically 12 V, 24 V or 48 V). It is rechargeable at least via the CV (current) converter. We consider in the following, by way of non-limiting example, that the BS utility battery is of the 12 V Lithium-ion type.

The electric driving machine MME is an electric machine arranged so as to provide torque to move the system S (here a vehicle) when it is supplied with electrical energy by the main battery BR, as well as possibly to recover torque in a regenerative braking.

The CV converter is also responsible during the driving phases of the system S (here a vehicle) of converting part of the electric current stored in the main battery BR to supply converted electric current to the on-board network RB and the utility battery BS ( to recharge it).

It will be noted, as illustrated without limitation in Figure 1, that the CV converter can be part of a CH charger also comprising a power calculator. AC recharge responsible, at least, for controlling the recharges of the main BR battery.

The main (or traction) battery BR can, for example, include electrical energy storage cells, possibly electrochemical (for example of the lithium-ion (or Li-ion) or Ni-Mh or Ni-Cd type). Also for example, the main battery BR can be of the low voltage type (typically 450 V for illustration purposes). But it could be medium voltage or high voltage.

It should also be noted that the main battery BR is associated with a battery box BB which notably includes a battery calculator CB.

The CR charging connector is coupled to the main battery BR and the charger CH via a charging line (or circuit) LR. It should also be noted that in the example illustrated non-limitatively in Figure 1, the charging line (or circuit) LR is double in order to allow the charging of the main battery BR in mode 2 or 3 as well as in mode 4. But the LR charging line (or circuit) can be simple when only charging in mode 2 or 3 is possible.

The CR charging connector is also coupled to an LC control line and a CD detection circuit of the S system.

The LC control line is arranged to allow exchanges of information with an external CE connector which is temporarily connected to the CR charging connector. This may be what those skilled in the art frequently call a control pilot line (or in English “control pilot line” (CPL)). It is preferably coupled to the CH charger which controls the recharges, as illustrated without limitation in Figure 1.

The detection circuit CD is arranged so as to detect the type of the external connector CE, and in particular whether it is suitable for recharging in mode 2, 3 or 4 or for powering at least one internal device Dlj, such as we will see it further. It may be what those skilled in the art frequently call a proximity line (or in English “proximity line”). In general, it is the specific value of a resistor, fitted to the external connector CE and temporarily coupled to the detection circuit CD, via the connector recharge CR, which allows the detection circuit CD to determine the type of the external connector CE. In this case, each type is associated with a specific resistance value.

It will be noted that in the example illustrated non-limitatively and at least partially in Figures 1 and 2 the external connector CE comprises at least one internal device Dlj and is responsible for ensuring the connection to the charging connector CR (of the system S) d 'an electrical power cable C2 which is also connected to an external (electrical) device DE to be supplied with electrical energy. Each internal device Dlj is capable of ensuring at least one chosen internal function when powered by a chosen voltage.

For example, this external DE device may be an electric bicycle. But it can be any electrical device or equipment external to the S system, and in particular a trailer, a caravan, a mobile home, a barbecue, or a device lighting.

Also for example, each internal function, provided by an internal device Dlj of the external connector CE, can be chosen from a function for controlling the operation of at least part of this external connector CE, a function for monitoring a part at least less of this external CE connector, a protection function of at least part of this external CE connector, an operation diagnostic function of at least part of this external CE connector, and a signaling function of at least an operating state of an internal device Dlj. It will be understood that such internal functions are intended to participate in securing the supply of electrical energy (from the system S) to each external device DE coupled to the external connector CE, via the electrical power cable C2 (to which the latter (CE) possibly belongs).

In the example illustrated non-limitingly in Figure 2, the external connector CE comprises three internal devices DI1 to DI3 (j = 1 to 3) connected in parallel to the terminals of the external connector CE which are intended to be coupled to the terminals of the connector CR recharge connected to the LC control line. But an external connector CE can include any number of internal devices Dlj, as long as this number is at least equal to a 1 ).

For example, the first internal device DI1 (j = 1) can provide a function of controlling the operation of at least part of the external connector CE. It can for example include at least one microcontroller.

Also for example, the second internal device DI2 (j = 2) can provide a monitoring function and a protection function for at least part of the external connector CE. It can for example include at least one electrical insulation controller and/or a temperature controller (thermal monitoring).

Also for example, the third internal device DI3 (j = 3) can provide a signaling function for at least one operating state of an internal device Dlj. It can for example include at least one light emitting diode (or LED (“light emitting diode”)).

It will also be noted that in the example illustrated non-limitingly in Figure 2, the external connector CE also includes a specific resistance RC whose value makes it possible to define its type, and an information device DF which are connected in parallel to the terminal of the external connector CE which is intended to be coupled to the terminal of the charging connector CR connected to the detection circuit CD. This information device DF is for example responsible for providing the connection state of its external connector CE to the detection circuit CD based on information provided (here) by the first DI1 and second DI2 internal devices. It can, for example, include at least one switchable resistor.

It should also be noted that in the example illustrated non-limitingly and at least partially in Figures 1 and 2, the external connector CE is part of the electrical power cable C2. But this is not obligatory. Indeed, the external connector CE can, for example, constitute an adapter to which an electrical power cable capable of electrically supplying at least one external device DE can be temporarily connected.

The DC control device, which equips the system S, comprises at least one selection circuit CS which is suitable for being installed on the control line LC between first SP1 and second SP2 sub-parts of the latter (LC), as illustrated in Figures 1 and 2. It is therefore interposed between the first SP1 and second SP2 sub-parts of the LC control line.

This selection circuit CS is also connected to an electrical supply circuit C1 which includes the system S, and which can provide at least one selected supply voltage. Note that the electrical supply circuit C1 can be supplied with electrical energy from the utility battery BS or the main battery BR. However, when the supply voltage is very low it is preferable for the electrical energy to come from the BS service battery. But we could envisage that the electrical energy comes from the main battery BR, via the CV converter (which then ensures at least part of its conversion). It will be understood that the electrical supply circuit C1 is arranged so as to generate at least one supply voltage chosen from a voltage which it receives, for example from the on-board network RB or from the CV converter. It can therefore include a voltage converter, in particular.

It will also be noted that the electrical supply circuit C1 can possibly be arranged so as to be able to provide at least two different supply voltages, adapted respectively to different needs of internal devices Dlj belonging to different external connectors. In this case, the electrical supply circuit C1 receives different commands corresponding respectively to the different supply voltages that it can supply and generated by the CC calculator described later.

For example, each supply voltage can be of the very low voltage type and between 3 V and 12 V. Thus, each supply voltage can be equal, for example, to 3.3 V or 5 V or 9 V or still 12 V.

The selection circuit CS is arranged so as to couple the charging connector CR to the electrical supply circuit C1 when the detected type of the external connector CE is representative of a need for electrical supply of at least one internal device Dlj of this external CE connector which is suitable for being coupled to the LC control line.

It will be understood that if the detected type of the external connector CE is representative of a recharge in mode 2, 3 or 4, the selection circuit CS is arranged so as to couple the first SP1 and second SP2 together. sub-parts of the LC control line so that recharging can take place. On the other hand, if the detected type of the external connector CE is representative of a need for power supply of at least one internal device Dlj, the selection circuit CS is arranged so as to couple the charging connector CR to the charging circuit power supply C1 so that each internal device Dlj of the external connector CE can be powered with the chosen supply voltage so that the power supply of at least one external device DE coupled to the external connector CE can be done in a secure manner.

This is particularly advantageous because the external CE connector no longer needs to include a rechargeable battery to power each of its internal Dlj devices, and therefore there is no longer any risk that the user will not be able to use it. (for a discharge problem) and its size is reduced, and if the option of powering the external CE connector is not provided in the S system it can either not be equipped with a DC control device, or configure the latter (DC) so that it permanently ensures the coupling between the first SP1 and second SP2 sub-parts of the control line LC to only allow recharges of the main battery BR.

It will be noted, as illustrated without limitation in Figures 1 and 2, that the selection circuit CS can be adapted to couple:

- either the charging connector CR to the electrical supply circuit C1 via the first sub-part SP1 of the control line LC in the event of receipt of a first command generated by a CC computer following receipt of a first piece of information of type generated by the CD detection circuit,

- either the first SP1 and second SP2 sub-parts of the control line LC in the event of receipt of a second command generated by the calculator CC following receipt of a second type of information generated by the detection circuit CD.

Each command can be of analog type (specific voltage or current) or digital (0 or 1), depending on the respective arrangements of the selection circuit CS and the calculator CC.

It will also be noted, as illustrated without limitation in Figures 1 and 2, that the DC control device can include the CC calculator. But this it's not mandatory. Indeed, the calculator CC can be embedded in the system S and arranged so as to perform several functions, including the supply of a first or second command to the selection circuit CS depending on the type of the external connector CE detected by the detection circuit CD and therefore depending on whether the latter (CD) generated a first or second type information. For example, the CC calculator could be the AC recharge calculator or the CB battery calculator associated with the main battery BR and located in the battery box BB.

The CC calculator comprises at least one processor, for example a digital signal processor (or DSP (“Digital Signal Processor”)), and at least one memory. The memory is RAM in order to store instructions for the implementation by the processor of electrical or electronic operations. The processor may include integrated (or printed) circuits, or several integrated (or printed) circuits connected by wired or non-wired connections. By integrated (or printed) circuit we mean any type of device capable of performing at least one electrical or electronic operation. This CC calculator can also include a mass memory, in particular for storing the first and second type information and any intermediate data involved in all its calculations and processing, an input interface for receiving at least the first and second type information to use them in calculations or processing, possibly after having formatted and/or demodulated and/or amplified them, in a manner known per se, by means of a digital signal processor, and an interface of output in particular to deliver the first and second orders.

For example, and as illustrated without limitation in Figure 2, the selection circuit CS can comprise a switch having first B1, second B2 and third B3 terminals. The first terminal B1 is connected to the first sub-part SP1 of the control line LC. The second terminal B2 is connected to the second sub-part SP2 of the control line LC. The third terminal B3 is connected to the power supply circuit C1. This switch is arranged so as to couple the first terminal B1 to the second terminal B2 or to the third terminal B3 depending on the type detected.

It will be understood that if the selection circuit CS receives a first command he configures his switch so that it couples the first terminal B1 to the third terminal B3 so that the internal devices DI1 are supplied with electrical energy, and as well as the power supply of at least one external device DE coupled to the external connector CE can be done in a secure manner. On the other hand, if the selection circuit CS receives a second command it configures its switch so that it couples the first terminal B1 to the second terminal B2 so that the main battery BR can be recharged.

Such a three-terminal switch can be produced using at least one electronic component.

Claims

1. Control device (DC) for a system (S) comprising a charging connector (CR) capable of being temporarily coupled to an external connector (CE) having a detectable type, and a control line (LC) connected to said connector recharge (CR) and allowing exchanges of information with said external connector (CE), characterized in that it comprises a selection circuit (CS) capable of being installed on said control line (LC) and of being connected to an electrical power supply circuit (C1) of said system (S), and capable of coupling said charging connector (CR) to said electrical power supply circuit (C1) when said detected type is representative of a need for electrical power of at least one internal device (Dlj) of said external connector (CE), capable of being coupled to said control line (LC).

2. Device according to claim 1, characterized in that said selection circuit (CS) is capable of coupling either said charging connector (CR) to said electrical power supply circuit (C1) via a first sub-part (SP1) of said control line (LC) in the event of receipt of a first command generated by a computer (CC) following receipt of first type information generated by a detection circuit (CD) equipping said system (S), connected to said charging connector (CR) and capable of detecting said type of external connector (CE), i.e. said first sub-part (SP1) to a second sub-part (SP2) of said control line (LC) in the event of reception of a second command generated by said computer (CC) following receipt of a second type information generated by said detection circuit (CD).

3. Device according to claim 2, characterized in that it comprises said calculator (CC).

4. Device according to one of claims 1 to 3, characterized in that said selection circuit (CS) comprises a switch having first (B1) and second (B2) terminals connected respectively to first (SP1) and second ( SP2) sub-parts of said control line (LC) and a third terminal (B3) connected to said electrical power supply circuit (C1), and capable of coupling said first terminal (B1) to said second (B2) or third ( B3) terminal according to said detected type.

5. System (S) comprising i) a charging connector (CR) capable of being temporarily coupled to an external connector (CE) having a detectable type, and ii) a control line (LC) connected to said charging connector (CR ) and allowing exchanges of information with said external connector (CE), characterized in that it further comprises an electrical supply circuit (C1) capable of supplying a chosen supply voltage, and a control device ( DC) according to one of the preceding claims, installed on said control line (LC) and connected to said electrical power supply circuit (C1).

6. System according to claim 5, characterized in that it comprises a detection circuit (CD) connected to said charging connector (CR) and capable of detecting said type of external connector (CE).

7. External connector (CE) having a detectable type and capable of being connected to a charging connector (CR) equipping a system (S) comprising a control line (LC) connected to said charging connector (CR) and allowing exchanges information with said external connector (CE), characterized in that it comprises at least one internal device (Dlj) capable of ensuring at least one chosen internal function when it is powered by a chosen voltage supplied by said system (S ) via said charging connector (CR) on terminals associated with said control line (LC).

8. External connector according to claim 7, characterized in that each internal function is chosen from a function for controlling the operation of at least part of said external connector (CE), a function for monitoring at least part of said connector external (CE), a protection function of at least part of said external connector (CE), an operation diagnostic function of at least part of said external connector (CE), and a signaling function of at least an operating state of an internal device (Dlj).

9. External connector according to claim 7 or 8, characterized in that it constitutes an adapter to which a cable (C2) capable of electrically supplying at least one external device (DE) can be temporarily connected.

10. Power supply cable (C2) for power supply to at least one external device (DE), characterized in that it comprises an external connector (CE) according to claim 7 or 8.