WO2020157394A1

WO2020157394A1 - Method for controlling a generator coupled with a one-way clutch of a motor vehicle

Info

Publication number: WO2020157394A1
Application number: PCT/FR2019/052981
Authority: WO
Inventors: Raphael COMTE; Bernard Boucly; Herve Perseval
Original assignee: Psa Automobiles Sa
Priority date: 2019-01-29
Filing date: 2019-12-09
Publication date: 2020-08-06
Also published as: FR3092208A1; FR3092208B1

Abstract

The present invention relates to a method for controlling two electricity production functions, the method comprising, when a freewheel mode of operation is activated: determining a first output voltage setpoint and a first current setpoint of the first electricity producer (21), the first voltage setpoint and the first current setpoint being configured to maintain a current intensity supplying the first storage (23) equal to zero and to maintain a voltage higher than a predefined threshold on the first network (24), determining a second output voltage setpoint and a second current setpoint of the second electricity producer of the second electricity producer (22), the second voltage setpoint and the second current setpoint being configured to maintain a current intensity supplying the second storage (29) equal to zero and to maintain a voltage higher than a predefined threshold on the second network (33).

Description

DESCRIPTION

TITLE: PROCESS FOR CONTROL OF A GENERATOR

TORQUE TO A FREEWHEEL OF A VEHICLE

AUTOMOTIVE

TECHNICAL FIELD AND OBJECT OF THE INVENTION

The present invention relates to a method of controlling a generator coupled to a freewheel, for example an alternator, an alternator-starter, a battery, of a motor vehicle.

A motor vehicle includes a computer configured to implement such a method for controlling a generator suitable for supplying an on-board electrical network.

STATE OF THE ART

According to the prior art, the control of the inverter inside a vehicle is configured to meet the needs of the heat engine.

There is a method of determining the freewheeling phases in a freewheeling drive train group where a combustion engine is coupled to an electric generator.

There is also known a combustion engine combined with a generator coupled to a freewheel and applying a current control method to provide energy.

The state of the art comprises the patent document FR2990579, which describes a method for controlling a generator suitable for supplying an on-board electrical network of a vehicle by a control device suitable for determining the value of a setpoint of generator voltage and to control the generator as a function of a current setpoint independent of the voltage setpoint.

However, such a solution has drawbacks because it does not take into account the use or not of the freewheel of the powertrain. Thus, energy is used unnecessarily.

The invention therefore aims to resolve these drawbacks by proposing a method for controlling a generator coupled to a freewheel where the electrical energy is managed by two separate electrical networks maintaining the state of charge of different electrical energy storage devices. (also referred to as "storers") while coasting. GENERAL PRESENTATION OF THE INVENTION

To achieve this result, the present invention relates to a method for controlling two electrical production functions for controlling on the one hand a first electrical producer, said first electrical producer supplying a first electrical network to which are connected, said first electrical producer and a first electrical energy storer, and on the other hand a second electrical producer, independent of the first electrical producer, said second electrical producer being connected between the first electrical network and a second electrical network to which is also connected a second electrical energy storer , said method comprising, when a freewheel operating mode is activated: determining a first output voltage setpoint of the first electrical generator,

determining a first current setpoint from the first electricity producer, independent of the first voltage setpoint,

in freewheel operating mode, said first voltage setpoint and said first current setpoint being configured to maintain an intensity of the current supplying the first storage device equal to zero and to maintain a voltage greater than a predefined threshold on the first electrical network ,

determining a second output voltage setpoint from the second power producer,

the determination of a second current setpoint from the second electricity producer, independent of the second voltage setpoint,

in freewheel operating mode, said second voltage setpoint and said second current setpoint being configured to maintain an intensity of the current supplying the second storage device equal to zero and to maintain a voltage greater than a predefined threshold on the second electrical network .

Advantageously, the activation of the freewheel operating mode of the first electric generator comprises a check of the state of charge of the first electric energy store, said check consisting in verifying that the state of charge of the first energy store electrical is greater than a threshold authorizing the activation of the freewheel operating mode of the first electrical producer. Advantageously, the activation of the freewheel operating mode of the first electrical generator comprises a check of at least one electrical component of the first electrical network if said threshold of the state of charge of the first electrical energy store is reached, said control consisting in verifying that said at least one electrical unit of the first electrical network is suitable for being supplied with the voltage of said first electrical network.

Advantageously, below said threshold, the activation of the freewheel operating mode of the first electricity producer is prohibited.

Advantageously, the method also comprises a step of reception, by a single supervisor of said second electrical network and of said first electrical network, of an authorization or prohibition of the freewheel operating mode of the first and / or of the second. electric producer.

Advantageously, the activation of the freewheel operating mode of the second electric generator comprises a check of the state of charge of the second electric energy store, said check consisting in verifying that the state of charge of the second energy store electric power is greater than a threshold authorizing the activation of the freewheel operating mode of the second electric generator.

Advantageously, if the voltage of the first electrical network is less than a first minimum safety voltage, the component of the current intensity setpoint I _CO ns of the second producer, which represents the setpoint to be applied to guarantee the first minimum voltage on said first electrical network, is increased, so that the current intensity setpoint I _CO ns increases up to the maximum intensity I _ma x of the first electrical producer.

Advantageously, if the voltage of the second electrical network is less than a second minimum safety voltage, the component of the current intensity setpoint I _CO ns of the second producer, which represents the setpoint to be applied to guarantee the second minimum voltage on said second electrical network, is increased, so that the current intensity setpoint I _CO ns increases up to the maximum intensity I _ma x of the second electrical producer.

The invention also relates to an electric motor vehicle comprising a computer configured to implement a method for controlling two electrical production functions, as briefly described above. PRESENTATION OF FIGURES

Other features and advantages of the invention will become apparent on reading the detailed description of the embodiments of the invention, given by way of example only, and with reference to the drawings which show:

[Fig. 1] is a diagram of a generator associated with a control device having a voltage setpoint and a current setpoint.

[Fig. 2] is a diagram of the functional architecture of a generator comprising two separate voltage networks.

[Fig. 3] shows a diagram of the electrical supply to the on-board electrical network from a voltage network.

DETAILED DESCRIPTION OF AN EMBODIMENT OF THE INVENTION

In what follows, reference is made to 12V and low voltage on-board electrical networks, and to electrical producers and electrical storage units connected to these 12V and low-voltage on-board electrical networks. However, in particular, the voltage level of the on-board electrical networks is given for illustrative purposes only and should not be interpreted as a limitation.

Figure 1 shows a diagram of a supervisor 1 associated with electrical producer 6. For example, the electrical producer is intended to supply an on-board electrical network of a vehicle.

The electrical producer delivers electrical energy as a function of a voltage setpoint U _cons 4 and a current setpoint I _COns 5 independent of the voltage setpoint U _{¥ ns} 4.

With reference to FIG. 2, the electrical storage devices 23, 29, for example a 12 V battery and a low-voltage lithium-type battery, are adapted to be supplied by a respective electrical producer and to supply electricity to the networks of edge 24, 33 respectively. Each electrical network 24, 33 comprises electrical components which are electrical consumers. Each electrical network 24, 33 is associated with an electricity producer, in other words a power converter configured to transfer energy to it.

Each electric generator makes it possible to regulate the recharging, the discharge and the constant maintenance of the load of the storage units 23, 29, corresponding to the life situation of the vehicle and the needs of the on-board electrical network 24, 33 respectively. Each electrical producer obeys voltage 4 and intensity 5 setpoints which are determined by a control device. Each storer 23, 29 can be considered, when it is used to supply electricity to the on-board electrical network 24, 33 respectively, as a generator.

The control device is thus suitable for controlling both a main generator of the vehicle, the alternator or the alternator-starter for example, and the electrical storage units 23, 29 associated with their respective on-board electrical network 24, 33, and this depending on the needs of the vehicle, its life situation, and the state of each electrical storage device 23, 29, said state being for example a function of the current, the voltage, the charge, the temperature, the aging, the internal resistance.

It is therefore possible to optimize the electrical transfers taking into account the constraints of each on-board electrical network 24, 33.

We see in Figure 1 a regulation structure 7 of the electricity producer 6 from a voltage setpoint U _CO ns 4 and a current setpoint I _CO ns 5. The supervisor 1 performs a first determination function 2. of the voltage setpoint 4 as well as a second function 3 for determining the current setpoint 5. A first loop provides voltage regulation by means of a voltage corrector 10 by comparing the voltage setpoint U _CO ns 4 with the voltage 8 delivered by the electrical producer 6. A second loop regulates the intensity by means of an intensity corrector 13 by comparing a current limitation intensity setpoint with the intensity delivered 9 by the electrical producer 6.

The electrical producer 6 also includes a current intensity limitation setpoint, equal to the maximum intensity I _max 12 that said electrical producer is able to provide. This maximum intensity value I _max 12 is linked to the structure of the electric generator 6; it can change as a function of the thermal evolution of the generator or of the supply voltage.

The use of voltage U _CO ns 4 setpoints and current I _CO ns 5 setpoints allows precise control of the power producer 6.

FIGS. 2 and 3 represent a diagram of the functional architecture of a system with two electrical generators, two separate voltage networks, in particular when a need for energy optimization in freewheel operating mode is requested. In general, the use of two independent supervisors involves risks of instability. Indeed, two autonomous supervisors are likely to give contradictory instructions, leading to fast or on the contrary slow actions, causing electrical and therefore also mechanical oscillations. This results in a use comprising imperfections such as intermittent shutdowns of electrical equipment. To avoid this, the supervisor combines two interconnected functions of a first low voltage supervisor 14 determining the voltage setpoint U _CO ns 4 and of a second 12V supervisor 30 determining the intensity setpoint I _CO ns 5.

The low-voltage supervisor 14 makes it possible to manage the state of charge 17 of the lithium-type electrical energy storage device 23. The low-voltage supervisor 14 can also broadcast useful information for defining instructions to be applied to the internal combustion engine 36. exchanges of information 18 between the internal combustion engine 36 and the low voltage supervisor 14 take place for example.

The low-voltage supervisor 14 also establishes the state of the low-voltage on-board electrical network 24 and receives information on the state of charge of said low-voltage on-board electrical network 24, for example during voltage variations, by measuring the voltage at at least one point of the low voltage on-board electrical network 24.

The low voltage supervisor 14 also sends control instructions 20 to a first electrical producer 21, for example a reversible inverter. Said reversible inverter 21 operates either in three-phase rectifier mode in order to operate the reversible electric machine 19 in generator mode, or as a three-phase inverter in order to operate the reversible electric machine 19 in motor mode.

Other exchanges of information 15 between the low voltage supervisor 14 and the 12V supervisor 30 also take place.

The 12V supervisor 30 establishes the voltage and current intensity control instructions 27 to the second electrical producer 22, for example a direct voltage to direct voltage converter, after having evaluated its state, according to the needs evaluated by the supervisor 1 of the vehicle.

The 12V supervisor 30 also receives information on the state of charge of the 12V electrical energy storage device 29.

The 12V supervisor 30 measures the voltage at at least one point of the 12V on-board electrical network 33 with the exception of the starter 35, to check the adequacy between said voltage and needs of the vehicle. In other words, the 12V supervisor 30 determines in particular whether the state of charge of electrical elements of the 12V on-board electrical network 33 considered to be sensitive to low or high voltage levels and during sudden voltage variations is adequate.

Just like the low voltage supervisor 14, the 12V supervisor 30 can also exchange information with the internal combustion engine 36 integrated in the vehicle and checks the state 31 of the starter 35.

When a need for energy optimization in freewheel operating mode is requested, the 12V on-board electrical network 33 is supplied with electricity without charging the 12V storage device 29. The reversible inverter 21 is controlled by a first voltage setpoint Ucons and a first current setpoint I _CO ns guaranteeing zero current intensity regulation 38 in the low-voltage storer 23. The control of the direct-to-direct voltage converter 22 is for its part carried out with a second voltage setpoint U _cons and a second current setpoint I _CO ns guaranteeing zero current intensity regulation 38 in the 12V storage device 29 as well as a minimum voltage 37 on the 12V network.

Initially, the conditions for being in freewheel operating mode at the level of the low voltage storage device 23 must be met. The state of charge of the low-voltage storage device 23 is checked; it must not be too low to avoid any risk related to safety or leading to degradation of the low-voltage storage device 23. Then, it is also checked that no component of the low-voltage electrical network 24 does not present an incompatibility with a voltage during the freewheeling phase, for example, the voltage must not be too low or that a so-called safe electrical device must not be activated. If these conditions are not met, then the freewheel operating mode for the low voltage electrical network is not authorized and the first and second setpoints for voltage regulation U _CO ns and current intensity I _CO ns by fault are applied, taking into account including the maximum current I _ma x 12. A diagnostic information signaling that the freewheel mode of the low voltage electrical network is not authorized can then be sent to the supervisor 1 of the vehicle.

On the other hand, if no incompatibility disturbs the freewheeling phase, that is to say if the minimum voltage constraints of the low voltage electrical network are respected, then the current intensity regulation setpoint I _CO ns of the storer low voltage 23 is set to zero 38. Finally, diagnostic information concerning the state of the freewheel operating mode of the low voltage electrical network is sent to the vehicle supervisor so that he knows the electrical state of the low voltage electrical network. and maintain or modify the phase of life.

Alternatively, if there is no consuming electrical device on the first low voltage electrical network 24, the voltage of the first storage device 23 can be used to ensure compliance with the minimum voltage of the low voltage electrical network. When the freewheel conditions at the level of the low voltage storer 23 mentioned above are not met, corresponding diagnostic information can be sent to the vehicle supervisor. In this case, as for the low voltage storer 23 previously, the state of charge of the 12V storer 29 is checked. If the state of charge of the 12V 29 storage device is too low or presents a safety risk or if it is degraded, then the freewheel mode for the 12V network is not authorized and the regulation of voltage U _CO ns 4 and of current intensity I _CO ns 5 by default, taking into account in particular the determined maximum intensity I _ma x 12.

Said maximum intensity I _ma x 12 is determined at least as a function of the state of the corresponding electrical producer. Diagnostic information concerning the state of the freewheeling mode of operation of the 12V onboard electrical network 33 can be sent to the vehicle supervisor 1 so that it knows the electrical status of the 12V onboard electrical network 33 and to maintain or modifies the phase of life.

However, if after checking the state of charge of the 12V storer, freewheel operating mode is maintained, then it is also checked that no electrical device of the 12V network is incompatible with the voltage of said 12V network during the phase of freewheel, for example in the case of too low a voltage, or when activating an electric safety device.

If any incompatibilities are detected, then the freewheel operating mode is not authorized and the setpoints for voltage regulation U _CO ns 4 and current intensity I _CO ns 5 are applied by default, taking into account in particular the maximum determined current I _max 12. A diagnostic information signaling that the freewheeling mode of the 12V network is not authorized can be sent to the vehicle supervisor 1.

If no incompatibility is detected, then the current intensity regulation function of the 12V storage device 29 is set to zero, the intensity is zero 38, and diagnostic information concerning the state of the freewheel operating mode of the 12V on-board electrical network 33 can be sent to the supervisor so that he knows the electrical state of the low voltage network and maintains or modifies the life phase.

The current intensity regulation function of the first and second power generators 21, 22 has a similar operation.

First, the measured current intensity is compared to the current intensity setpoint, for each power producer 21, 22.

The first current intensity setpoint concerns the first electrical producer 21 and the second current intensity setpoint concerns the second producer 22.

The first current intensity setpoint I _CO ns of the first electrical producer 21, respectively the second current intensity setpoint I _CO ns of the second electrical producer 22, corresponds to a minimum between a function for limiting the maximum intensity I _ma x 12 and the sum of the current intensities Icc and Icv, Isc being the component of the current intensity setpoint I _CO ns which represents the value to be applied to regulate the first electrical storage device 23, respectively the second electrical storage device, , and Icv being the component of the current intensity setpoint I _CO ns which represents the setpoint to be applied to guarantee the minimum voltage on the on-board electrical network, respectively on the second on-board electrical network.

If the current intensity of the low voltage storage device 23 measured is negative, according to the invention, the component Icc of the current intensity setpoint I _CO ns, which represents the value to be applied to regulate the corresponding electrical storage device with current is increased, so that the current intensity of the low voltage storer 23 increases while remaining lower than the maximum intensity I _ma x 12.

If the measured current intensity is zero, then the component Isc of the current intensity setpoint I _CO ns, which represents the value to be applied to regulate the corresponding electrical storage device with current, is maintained, so that the intensity of current of the low voltage storer 23 is maintained.

If the measured current intensity is positive, the component Isc of the current intensity setpoint I _CO ns, which represents the value to be applied to regulate the current the corresponding electrical storage device is reduced, so that the current intensity of the low voltage storage device 23 decreases.

If the measurement of the voltage of the on-board electrical network 33 is less than a first minimum safety voltage, the component Icv of the current intensity setpoint I _CO ns, which represents the setpoint to be applied to guarantee the minimum voltage on the on-board electrical network 33, is increased, so that the current intensity setpoint I _CO ns increases up to the maximum intensity I _ma x 12 of the corresponding electrical producer.

It is recalled that the value of the maximum intensity I _ma x 12 is different depending on the operating mode of the electricity producer considered. The maximum intensity I _ma x 12 is in fact a function of the state of the electrical producer, of the state of the electrical storage device and of the operating mode of the electrical producer; it makes it possible to manage the functional or degraded modes, for example by reducing the value of the maximum intensity I _max 12 depending on the thermal conditions. Imax can also be limited by an external need, for example to limit torque extraction.

If the voltage of the on-board electrical network 33 measured is between the minimum safety voltage and the component Icv of the current intensity setpoint I _CO ns, which represents the setpoint to be applied to guarantee the minimum voltage on the electrical network of edge, then the component Icv of the current intensity setpoint I _CO ns is maintained.

If, on the other hand, the measurement of the voltage of the on-board electrical network 33 is the same or greater than the minimum voltage value, then the component Icv of the current intensity setpoint I _CO ns for the 12 V storage device 29 decreases as much that it remains positive. Indeed, the current intensity of the 12 V storage device 29 cannot be less than zero because it allows the calculation of the current setpoint I _CO ns.

For each on-board electrical network 24,33, if the voltage is identical to or greater than the value of the corresponding minimum voltage, then the respective current setpoint I _COns for each on-board electrical network 24, 33 represents the control carried out on a storer or on the electricity producer.

In addition, if the voltage of the on-board electrical network 24 is less than a second minimum voltage, then the current regulation setpoint assigned to the first electrical generator is increased and therefore the current intensity of the 12 V storage device 29 increases. Thus, the current intensity of the low-voltage storage device 23 decreases until it becomes zero and the intensity setpoint I _CO ns 5 consists in fixing the current intensity of the 12 V storage device 29.

By definition, the voltage setpoint U _CO ns corresponds to a voltage setpoint intended respectively for each electricity producer. This may be the nominal voltage to be applied to the on-board electrical network 24 or 33, in particular in the operating mode of the corresponding electrical producer in voltage regulation like a conventional alternator. It may also be the maximum value admissible by the on-board electrical network 24 or 33, this value being reached by increasing the current setpoint I _CO ns, the current setpoint I _CO ns being used to limit the current delivered. by the corresponding electricity producer.

The method according to the invention therefore makes it possible to authorize or prohibit a freewheel operation of the electric producer when charging two different electric accumulators, in an electric or hybrid vehicle.

Claims

1. Method for controlling two electrical production functions to control on the one hand a first electrical producer (21), said first electrical producer (21) supplying a first electrical network (24) to which said first electrical producer (21) are connected. and a first electrical energy store (23), and on the other hand a second electrical producer (22), independent of the first electrical producer (21), said second electrical producer (22) being connected between the first electrical network (24). ) and a second electrical network (33) to which is also connected a second electrical energy store (29), said method comprising, when a freewheel operating mode is activated:

determining a first output voltage setpoint from the first electricity producer (21),

the determination of a first current setpoint from the first electrical producer (21), independent of the first voltage setpoint,

in freewheel operating mode, said first voltage setpoint and said first intensity setpoint being configured to maintain an intensity of the current supplying the first storer (23) equal to zero and to maintain a voltage greater than a predefined threshold on the first electrical network (24),

determining a second output voltage setpoint from the second power producer (22),

the determination of a second current setpoint from the second electrical producer (22), independent of the second voltage setpoint,

in freewheel operating mode, said second voltage setpoint and said second current setpoint being configured to maintain an intensity of the current supplied to the second storer (29) equal to zero and to maintain a voltage greater than a predefined threshold on the second electrical network (33).

2. Method according to claim 1, characterized in that the activation of the freewheel operating mode of the first electrical producer (21) comprises a control of the state of charge of the first electrical energy store (23), said control consisting in verifying that the state of charge of the first electrical energy store (23) is greater than a threshold authorizing the activation of the freewheel operating mode of the first electrical producer (21).

3. Method according to claim 2, characterized in that the activation of the freewheel operating mode of the first electrical producer (21) comprises a check of at least one electrical member of the first electrical network (21) if said threshold of the state of charge of the first electrical energy store (23) is reached, said check consisting in verifying that said at least one electrical unit of the first electrical network (24) is suitable for being supplied with the voltage of said first electrical network ( 24).

4. Method according to claim 3, characterized in that, below said threshold, the activation of the freewheel operating mode of the first electrical producer (21) is prohibited.

5. Method according to one of the preceding claims, characterized in that it comprises a reception step, by a single supervisor of said second electrical network (33) and of said first electrical network (24), of an authorization or prohibition of the freewheel operating mode of the first and / or of the second electrical producer (22).

6. A method of controlling an electrical producer according to one of the preceding claims, characterized in that the activation of the freewheel operating mode of the second electrical producer (22) comprises a control of the state of charge of the second. electrical energy storage device (29), said check consisting in verifying that the state of charge of the second electrical energy storage device (29) is greater than a threshold authorizing the activation of the freewheel operating mode of the second electrical generator (22).

7. Method according to one of the preceding claims, wherein, if the voltage of the first electrical network (24) is less than a first minimum safety voltage, the component (Icv) of the current intensity setpoint I _CO ns of the second producer (22), which represents the setpoint to be applied to guarantee the first minimum voltage on said first electrical network (24), is increased, so that the current intensity setpoint I _CO ns increases up to the maximum intensity I _ma x (12) of the first electrical producer (21).

8. Method according to one of the preceding claims, wherein, if the voltage of the second electrical network (33) is less than a second minimum safety voltage, the component (Icv) of the current intensity setpoint I _CO ns of the second producer (22), which represents the instruction to be applied to guarantee the second minimum voltage on said second electrical network (33) is increased, so that the current intensity setpoint I _CO ns increases up to the maximum intensity I _max (12) of the second electrical producer (21).

9. Electric motor vehicle comprising a computer configured to implement a method for controlling two electrical production functions according to one of the preceding claims.