EP2628234A1

EP2628234A1 - Method of recharging a supercapacitor module for a motor vehicle, and corresponding motor vehicle

Info

Publication number: EP2628234A1
Application number: EP11771256.2A
Authority: EP
Inventors: Patrice Cinneri; Aurelien Mallet
Original assignee: Peugeot Citroen Automobiles SA
Current assignee: PSA Automobiles SA
Priority date: 2010-10-14
Filing date: 2011-09-22
Publication date: 2013-08-21
Also published as: WO2012049387A1; FR2966294A1; FR2966294B1

Abstract

The invention relates to a method of recharging a supercapacitor module (44) of an internal combustion engine motor vehicle at rest and of automatic restarting, the on-board network (20) comprising at least one electrical consumer (66) providing a security service for the motor vehicle, the method comprising: the determination of the state of activation of the at least one sensitive electrical consumer (66); the determination of the power consumption of the at least one sensitive electrical consumer (66) in the activated state; the generation of a setpoint current for recharging the supercapacitor module (44) available from the difference between the electrical energy that the starter-alternator (64) can produce and the power consumption of the at least one sensitive electrical consumer (66) in the activated state so as to take account of the maintenance of the power supply for the at least one sensitive electrical consumer (66). The invention also relates to a vehicle comprising a computer for implementing the method of the invention.

Description

METHOD FOR RECHARGING A SUPERCONDENSING MODULE OF A MOTOR VEHICLE AND CORRESPONDING MOTOR VEHICLE

The present invention claims the priority of the French application 1058376 filed October 14, 2010 whose content (text, drawings and claims) is here incorporated by reference.

[Ooo2] The invention relates to a method of charging a supercapacitor module of a motor vehicle. The invention furthermore relates to a motor vehicle with an automatic stop and restart device and capable of implementing the charging method of a supercapacitor module of the vehicle.

[ooo3] In the field of motor vehicles with stop and automatic restart device of the engine, (said vehicle Stop & Start) the engine is automatically cut off when the vehicle is stopped. The heat engine is then restarted quickly using an alternator-starter in starter mode. In addition to the alternator-starter, these motor vehicles may include a conventional starter to ensure the starting of the engine after extended parking. These motor vehicles are also known as micro-hybrid vehicles and their main objective is the reduction of greenhouse gas emissions. [Ooo4] The alternator-starter or the starter are electrically powered by the on-board network of the motor vehicle. The voltage of the onboard network is conventionally imposed by a battery of the on-board network. The onboard network of these vehicles conventionally includes an additional energy store that functions as a reservoir of electrical energy in the event of a voltage drop due to a restart. The additional energy store is also known as the supercapacitor or ultracapacitor module (UCAP).

[ooo5] By means of a specific control electronics controlling suitable switches, the UCAP can be:

• put in series with the battery, to contribute to the start-up services, by contributing to the starter's power supply, and restarting, by contributing to the power supply of the alternator-starter (operating mode while maintaining the on-board network voltage);

• paralleled in the on-board network via a voltage converter, to ensure its recharging when the engine is running or stopped (operating mode when reloading the onboard network voltage);

• electrically isolated when the electrical system does not require the contribution of the UCAP and that it is loaded or when the safety of the vehicle requires it.

[ooo6] UCAP's contribution to the start-up and restart services ensures the maintenance of the on-board system voltage. The assembly formed by the UCAP, the voltage converter, and the switches forms a device known as the device for maintaining the voltage of the on-board network or the device for supporting the on-board network voltage.

[ooo7] During the reload mode of the supercapacitor module, the voltage converter (and more generally the entire voltage maintenance device) can be considered as an electrical consumer, drawing current to the on-board network. It is useful to determine the consequences of this power consumption.

[Ooo8] It is known from FR 2 930 688, a method of using a supercapacitor limiting the effective current supplied to the supercapacitor to prevent aging of the supercapacitor. Such a method however does not take into account the consequences of the power consumption of the supercapacitor module on the quality of the rest of the onboard network.

[Ooo9] There is therefore a need for a reloading method of a supercapacitor module that maintains the quality of the rest of the vehicle network of the vehicle with automatic stop and restart device.

[ooi o] For this, the invention provides a method for charging a supercapacitor module within a device for maintaining the voltage of the onboard network of a motor vehicle with a stop and automatic restart device, the motor vehicle further comprising a heat engine and an alternator starter electrically connected to the on-board network, the on-board network comprising at least one sensitive electrical consumer providing a function corresponding to a safe performance of the motor vehicle, the method comprising:

· Determining the activation status of the at least one sensitive electrical consumer;

Determining the power consumption of the at least one sensitive electrical consumers in the activated state;

The development of a charging current of the supercapacitor module available from the difference between the electrical energy that the alternator-starter can produce and the power consumption of the at least one sensitive electrical consumers in the activated state in order to take into account the maintenance of the power supply of the at least one sensitive electrical consumer. [Ooi i] According to one variant, the developed setpoint current has a zero intensity.

According to a variant, the at least one sensitive electrical consumer is chosen from the group of sensitive consumers consisting of:

• headlights of the motor vehicle;

• an anti-lock braking system of the vehicle wheels;

· An airbag control computer.

[Ooi3] According to one variant, before the step of generating the charging reference current, the method furthermore comprises:

• measuring an excitation current of the alternator-starter in an alternator operating mode;

the development of the setpoint current taking into account the excitation current of the alternator-starter by reducing the setpoint current developed when the measured excitation current exceeds a predetermined threshold.

According to a variant, taking into account the excitation current of the alternator-starter, the intensity of the charging reference current is reduced by at least 25%, preferably reduced by at least 50%. According to a variant, before the step of generating the charging reference current, the method furthermore comprises:

• the measurement of a temperature of the supercapacitor module in a mode of operation in reloading;

· The development of the setpoint current taking into account the temperature measured by reducing the setpoint current developed when the measured temperature exceeds a predetermined threshold.

[Ooi 6] According to one variant, following the measurement of the temperature of the supercapacitor module, the method comprises:

· The inhibition of automatic shutdowns and restart of the engine as long as the temperature exceeds the predetermined threshold.

According to a variant, the method further comprises:

• comparing the measured temperature of the supercapacitor module with a critical temperature threshold;

the development of the setpoint current taking into account the measured temperature by developing a reference current of zero intensity when the measured temperature exceeds the critical temperature threshold.

[Ooi 8] According to a variant, before the step of generating the charging reference current, the method furthermore comprises:

· Measurement of the voltage at the terminals of the supercapacitor module;

the development of the setpoint current taking into account the voltage measured by increasing the setpoint current developed when the voltage at the terminals of the supercapacitor module is strictly less than a predetermined voltage threshold.

The invention also proposes a motor vehicle with a stop device and automatic restart including an onboard network provided with a device for maintaining the voltage of the on-board network with a supercapacitor module, the vehicle further comprising , connected to the on-board network, a computer, an alternator-starter and at least one sensitive electrical consumer ensuring a function corresponding to a safe delivery of the motor vehicle, the computer being able to implement the above method. Other features and advantages of the invention will appear on reading the following detailed description of the embodiments of the invention, given by way of example only and with reference to the drawings which show:

FIG. 1, a synthetic diagram of the architecture of an onboard network of a motor vehicle of the Stop & Start type;

FIG. 2, a block diagram of the management of the charging current setpoint according to an embodiment of the method for generating the reference current.

The invention relates to a method for charging a supercapacitor module. The supercapacitor module is disposed within a device for maintaining the voltage of the on-board network of a motor vehicle with a stop and automatic restart device. The term "automatic shutdown and restart" relates to a heat engine that includes the motor vehicle. In the following description the term "supercapacitor module" is used regardless of the term "ultracapacity" or its abbreviation "UCAP". Similarly, the term "automotive vehicle stop device and automatic restart" is used regardless of the term "Stop & Start vehicle" or its abbreviation "vehicle STT".

FIG. 1 shows a synthetic diagram of the onboard network 20 of the vehicle STT. Thus, the vehicle STT comprises an alternator-starter 64 electrically connected to the edge network 20. The vehicle edge network 20 further comprises at least one electrical consumer 66 providing a function corresponding to a safe performance of the motor vehicle. Such an electrical consumer 66, associated with a safety service of the motor vehicle is called sensitive electrical consumer 66, in the following document.

The sensitive consumer 66 is for example selected from the group of sensitive consumers consisting of:

• headlights of the motor vehicle;

• an anti-lock braking system of the vehicle wheels;

· An airbag control computer. The proposed method comprises determining the activation state of the at least one sensitive electrical consumer 66. The method then comprises determining the power consumption of the at least one sensitive electrical consumers 66 in the activated state. That is to say that the electrical energy consumed by all the sensitive electrical consumers 66 in the activation state is determined.

Finally, the method comprises the development of a charging reference current of the UCAP 44. The development of the charging reference current according to the proposed method takes into account the maintenance of the power supply of the at least one responsive electrical consumer 66. The available charge charging current is determined from the difference between the electrical energy that can be generated by the alternator-starter 64 and the power consumption of the at least one sensitive electrical consumers 66 in the activated state in order to take into account the maintenance of the power supply of the at least one sensitive electrical consumer 66.

During a charging mode of the UCAP 44, the alternator-starter 64 is in alternator mode of operation, so it is the alternator-starter 64 that produces the electrical energy consumed for reloading of the UCAP 44. Because of the maintenance of the electrical power supply of the sensitive electrical consumer 66, all of the energy production of the alternator-starter 64 in an alternator mode of operation is no longer available for reloading the supercapacitor module 44 by the charging reference current. Only a residual electrical energy is available corresponding to the difference between the power generation of the alternator-starter 64 in an alternator operating mode and the consumption of the at least one sensitive electrical consumer 66.

In general, a charging high charging current and causing a systematic fast load UCAP 44 can be considered optimal from the point of view of the contribution to Stop & Start benefits. However, such an optimal current may represent too much of the electrical energy production of the alternator-starter 44, and deprive the onboard network 20 of the electrical energy necessary to maintain the quality of the network. In other words, this optimum recharging current can result in a charging electric energy consumption of the UCAP 44 strictly greater than the electrical energy residue, whereas the set current developed by the method is limited to what is available after the power supply of the electrical consumers, thus taking into account the maintenance of the power supply of the sensitive electrical consumers 66.

Thus, the recharging setpoint current is reduced while taking into account the maintenance of the electrical power supply of the sensitive electrical consumers 66. The setpoint current produced according to the proposed method makes it possible to condition the recharging of the UCAP 44 by the state of the network. and especially when sensitive electrical consumers 66 are engaged. Such an elaboration of the recharging setpoint current leads to a prioritization of the electrical energy consumption of the at least one sensitive electrical consumer 66 with respect to the power consumption for reloading the UCAP 44.

The challenge of the proposed method lies in the management of the current level taken to ensure the recharge of the UCAP 44, with the compromise of a load as fast as possible but also the most respectful of the quality of the network 20. Maintaining the quality of the on-board system includes the maintenance of safe services provided by sensitive consumers 66 on the shipboard system.

Ultimately, the above method allows to obtain a setpoint current for reloading a supercapacitor module that maintains the quality of the rest of the vehicle network of the vehicle to stop and automatic restart device.

Returning, in FIG. 1, the edge network 20 comprises the device 40 for maintaining the voltage of the on-board network 20. The voltage maintaining device 40 comprises a voltage converter 48 converting the voltage of the network of edge 20 in a voltage across the UCAP 44. The voltage converter makes it possible to impose a reloading of the UCAP 44 with the intensity of the recharging setpoint current produced according to the method previously described. The network 20 further comprises a battery 32 for supplying the voltage of the onboard network 20 to the various components of the edge network 20. Thus the alternator-starter 64, the sensitive electrical consumers 66, the holding device 40 are set in branch with respect to the battery 32. The battery 32 is for example a lead battery 1 2V.

The onboard network 20 also comprises a starter 62 shunted with respect to the battery 32. The starter 62 provides a starting function of the engine after prolonged parking of the vehicle, while the alternator-starter 64 ensures a function for restarting the engine of the vehicle following an automatic stop as part of the Stop & Start function. The alternator-starter 64 is also called reversible alternator. The motor vehicle conventionally comprises an accessory facade driven by a belt to link the operation of the onboard network 20 to the operation of the engine. The alternator-starter 64 thus has a mode of operation in starter mode, wherein the alternator-starter is a drive member of the vehicle accessory facade belt, for transmitting a starting torque to the engine. The starter 62 is also a drive member of the accessory facade belt of the vehicle. The alternator-starter 64 still has a mode of operation in alternator mode in which the alternator-starter recovers the mechanical energy of the rotating heat engine to transform it into electrical energy that it supplies to the network to recharge the battery 32 and the battery. UCAP 44.

The voltage maintaining device 40 comprises a first switch 42 and a second switch 46. The voltage maintaining device 40 switches from the operating mode to reload in operating mode in maintaining the network voltage according to the state of these switches 42 and 46. The first switch 42 is disposed between the negative pole of the battery 32 and one of the terminals of the UCAP 44, the other terminal of the UCAP 44 being connected to the ground 28 of the onboard network 20 through the voltage converter 48. The second switch 46 is disposed between the negative pole of the battery 32 and the ground 28 of the edge network 20. In the operating mode restart, the first switch 42 is in the pass position, while the second switch 46 is in the open position. Thus, the first switch 42 electrically connects the battery 32 in series with the UCAP 44. By this switching of the UCAP 44, the energy of the UCAP 44 can ensure the maintenance of the voltage of the onboard network 20. this mode of operation in restart, the electrical energy of the UCAP 44 then decreases gradually so that after a restart, it is useful to provide the reloading of the UCAP 44. The onboard network can include a mode of operation in startup, where the position of the switches 42 and 46 is the same as restarting. During such a mode of operation at startup, the UCAP 44 then functions as an additional energy storage starter support that ensures the start or support of the alternator-starter 64 that assists the starter. The use of the UCAP 44 during startup (that is to say after prolonged parking), provides the advantage of a fast start even in the case of a very cold engine, in connection for example with the conditions climate.

In the reload mode of operation, the first switch 42 is open and the second switch 46 is passing. The second switch 46 then connects the battery 32 directly to the ground 28 and the UCAP 44 is electrically connected in parallel with the battery 32 by the branch comprising the converter 48. The converter 48 corresponds to a down converter or to a DC converter / DC (direct current / direct current), voltages used in an onboard network being generally continuous. The converter 48 here causes a flow of electric current from the positive terminal of the battery 32 to the UCAP 44. In such a mode of operation reloading, the electrical energy consumed for reloading the UCAP depends on the current outputted by the converter 48. The converter 48 is then controlled to deliver a recharging current equal to the setpoint current produced according to the previously described method. The converter 48 is for example controlled using a motor vehicle calculator. So when the UCAP has already been used to maintain the voltage of the network during a restart, the converter 48 reloads the UCAP by imposing the setpoint current.

The network 20 may further include a mode of operation where the UCAP 44 is isolated from the onboard network. Reloading UCAP 44 is no longer possible. In such a mode of operation, the developed charging reference current has a zero intensity. The power supply to sensitive consumers can thus be maintained even if it stops charging UCAP 44.

The network finally comprises a wiring 68 for electrically connecting the various components of the previously described onboard network.

The previously described onboard network 20 is disposed in an STT vehicle. Such a motor vehicle may comprise a further computer capable of implementing the previously described method. Thus the invention also relates to such a motor vehicle. The following description describes more particularly the implementation of preferred embodiments of the method with respect to the network 20.

Maintaining the quality of the onboard network may also consist of taking into account the state of energy production of the alternator-starter 64. The state of production is based on the information of the Cyclic Opening Ratio of the alternator-starter 64 (abbreviated to RCO), which is the image of an excitation current of the alternator-starter 64. Thus before the elaboration of the charging reference current the method may comprise measuring an alternator-starter excitation current in an alternator mode of operation.

The higher the excitation current of the alternator-starter 64, the higher the RCO and the more the alternator-starter 64 produces energy. The more the alternator-starter 64 produces energy to ensure the overall consumption of electrical energy in the on-board network 20 and the less its potential to provide a backup for the recharge of the UCAP 44 is important because of a the alternator / starter saturation phenomenon 64. When the measured excitation current exceeds one predetermined threshold, it is thus possible to develop a reference current having an intensity corresponding to a slow recharge of the UCAP 44. The elaboration of the charging reference current then takes into account the excitation current of the alternator-starter 64 in reducing the developed setpoint current to a slow recharge setpoint current. The intensity corresponding to a slow recharge of the UCAP 44 corresponds, for example, to a reduction of at least 25% of the intensity of the charging setpoint current developed. This slow recharge intensity of the UCAP 44 preferably corresponds to a reduction of at least 50% of the refill setpoint current developed. It is therefore possible to weight the recharge of the UCAP 44 according to the ability to produce energy of the alternator-starter 64. In such an embodiment, it takes into account the external constraints to the onboard network 20 (such as the activation of non-sensitive functions of the motor vehicle due to external conditions) via a prioritization between the power supply of all the consumers of the on-board electrical system 20 and recharging of UCAP 44 via the charge of the reversible alternator 64.

The maintenance of the quality of the onboard network may also consist of taking into account the internal constraints of the onboard network, such as heating of the UCAP 44 and / or the associated voltage converter 48. The converter 48 and the UCAP 44 being considered current consumers in reloading mode of operation, they are subject to overheating (Joule effect) that can be harmful to them. Thus, a limitation of the charging current setpoint can be applied depending on their thermal state. Accordingly, prior to developing the recharge setpoint current, the method may include measuring a temperature of UCAP 44 in a reload operating mode.

In a preferred embodiment, the part of the computer (or microcontroller) associated with the UCAP 44 returns a thermal state at 3 levels depending on the temperature measurement of the converter 48 and that of the UCAP 44 At each thermal level is associated nominal operation (level_0) or operation in degraded mode (level_1 and level_2). At level_0, the stop is allowed (provided that all other conditions of authorization are respected) and all current load levels are allowed (slow load and fast charge).

At level_1, the stop is prohibited and only a slow charge is allowed. Thus, the proposed method can develop a reference current for recharging whose intensity corresponds to a slow recharge current of the UCAP 44 when the measured temperature exceeds the temperature threshold of level_1. Moreover, the proposed method can also inhibit the automatic shutdowns and restart of the engine as long as the temperature exceeds the temperature threshold of level_1. It is then taken into account in the elaboration of the charging setpoint of the measured temperature, when the temperature exceeds the temperature threshold of the level_1.

At level_2, the stop is always prohibited and no charge is allowed. Thus, the method can compare the measured temperature of the supercapacitor module with the critical temperature threshold of level 2. The charging reference current can then be developed with zero intensity when the measured temperature exceeds this critical temperature threshold. It is then taken into account in the elaboration of the charging setpoint of the measured temperature, when the temperature exceeds the temperature threshold of level_2. Such strategies for developing the reference current reloading preserve the UCAP 44 and the converter 48 in the case where they are at critical temperature levels.

The development of the reference current can also take into account the voltage at the terminals of the UCAP 44. The method then comprises the measurement of the voltage across the UCAP 44, before the development of the setpoint current. , so that the development of the reference current takes into account the measured voltage.

If the voltage is particularly low (for example after a stop or prolonged parking of the vehicle), a priority to recharge can be given according to the voltage across the UCAP 44. For example, the higher the voltage is low, the higher the priority. In other words, a high refill target current may be required to quickly return to an acceptable stored energy level, when the voltage across the supercapacitor module is strictly less than a predetermined voltage threshold. Thus, in such a case the intensity of the reference current for recharging can be elaborated so as to be equal to the intensity of a high fast charging current of the UCAP 44. In addition the high intensity of current The fast charging system can be designed to decrease as the expected voltage level is approached so that the UCAP 44 meets the nominal performance of the Stop & Start function, that is to say when the UCAP 44 stores enough electrical energy.

The set of previously described parameters can be represented synoptically in FIG. 2. The elaboration of the reference current for recharging the UCAP 44 then corresponds to a management of the charging current setpoint by taking into account account of these different parameters. The charging current setpoint is then sent to the converter 48 which imposes the reference current to the UCAP 44. According to one embodiment of the method, different arbitrations can be made between all these parameters, in order to determine a current setpoint of charging that ensures a compromise between charging time, protection of the UCAP 44 and the converter and the power supply of the onboard network 20.

According to one embodiment of the proposed method, the setpoint current is developed only in certain phases of life of the motor vehicle. The setpoint current is thus developed during a mode of operation in reloading of the UCAP 44. This mode of operation in reloading can intervene at least during two phases of life of the motor vehicle:

A phase of life where the engine is running, the alternator-starter 64 then reloads the UCAP 44,

A phase of life where the engine is cut off and / or stalled, the battery 32 then reloads the UCAP 44.

In contrast, it is preferred that the target current is not developed during other phases of life of the vehicle, for example: • during a restart mode of operation, when the UCAP 44 is potentially in series to perform support, or

• At the time of stopping the heat engine, the UCAP 44 is then isolated so as not to disturb the battery 12V, the battery then manages only the supply of the on-board network 20 because the alternator-starter 64 does not turn.

The proposed method, protecting the UCAP 44 and the converter 48 improves their life and limits their replacement. An economic advantage is thus induced by the method previously described.

Claims

A method of recharging a supercapacitor module (44) within a device (40) for maintaining the voltage of the onboard network (20) of a motor vehicle with a device for stopping and automatic restarting, the motor vehicle further comprising a heat engine and an alternator-starter (64) electrically connected to the on-board network (20), the edge network (20) comprising at least one sensitive electrical consumer (66) providing a function corresponding to a safe delivery of the motor vehicle, characterized in that the method comprises:

· Determining the activation status of the at least one sensitive electrical consumer (66);

• determining the power consumption of the at least one sensitive electrical consumers (66) in activated state;

The development of a charging current of the supercapacitor module (44) available from the difference between the electrical energy that the alternator-starter (64) can produce and the power consumption of the at least one electrical consumers responsive (66) in activated state to account for maintaining the power supply of the at least one sensitive electrical consumer (66).

2. The method according to claim 1, characterized in that the developed target current has a zero intensity.

3. The method according to claim 1 or 2, characterized in that the at least one sensitive electrical consumer (66) is selected from the group of sensitive consumers consisting of:

· Headlights of the motor vehicle;

• an anti-lock braking system of the vehicle wheels;

• an airbag control computer.

4. The method according to one of claims 1 to 3, characterized in that before the step of elaboration of the charge reference current, the method further comprises:

• measuring an excitation current of the alternator-starter (64) in an alternator mode of operation; the development of the setpoint current taking into account the excitation current of the alternator / starter (64) by reducing the setpoint current developed when the measured excitation current exceeds a predetermined threshold.

5. The method according to claim 4, characterized in that, taking into account the excitation current of the alternator-starter (64), the intensity of the charging reference current is reduced by at least 25%, preferably reduced by at least 50%.

6. The method according to one of claims 1 to 5, characterized in that, prior to the step of developing the charge reference current, the method further comprises:

Measuring a temperature of the supercapacitor module (44) in a recharging mode of operation;

• the development of the setpoint current taking into account the temperature measured by reducing the setpoint current developed when the measured temperature exceeds a predetermined threshold.

7. The method according to claim 6, characterized in that, following measurement of the temperature of the supercapacitor module (44), the method comprises:

• The inhibition of automatic shutdowns and restart of the engine as long as the temperature exceeds the predetermined threshold.

8. The process according to claim 6 or 7, characterized in that the process further comprises:

• comparing the measured temperature of the supercapacitor module (44) with a critical temperature threshold;

9. The method according to one of claims 1 to 8, characterized in that, prior to the step of developing the charge reference current, the method further comprises:

Measuring the voltage at the terminals of the supercapacitor module (44);

the development of the reference current taking into account the voltage measured by increasing the setpoint current developed when the voltage across the terminals of the supercapacitor module (44) is strictly less than a predetermined voltage threshold.

10. A motor vehicle with an automatic stop and restart device comprising an onboard network (20) provided with a device (40) for maintaining the voltage of the on-board network (20) with a supercapacitor module (44), the vehicle further comprising, connected to the on-board electrical system, a computer, an alternator-starter (64) and at least one sensitive electrical consumer (66) providing a function corresponding to a safe performance of the motor vehicle, the motor vehicle being characterized in that that the computer is able to implement the method according to one of claims 1 to 9.