FR3126503A1 - METHOD OF EXTENDING A USETIME OF A BATTERY - Google Patents

Abstract

One aspect of the invention relates to a method (100) of extending a life of a battery having a plurality of cells, said method (100) comprising the steps, performed by a computer, of: determining ( 102) a force applied to a wall of at least one cell of the battery, determining (103) a maximum authorized state of charge of the at least one cell as a function of the determined applied force. Figure 3

Description

METHOD OF EXTENDING A USETIME OF A BATTERY

The subject of the invention is the management of the charge of a battery, in particular the management of the charge of a battery for an electric or hybrid motor vehicle.

Such batteries generally comprise a plurality of electric accumulators, also called cells. Each cell comprises an electrochemical system able to be recharged up to a maximum voltage in no-load condition.

The batteries are generally controlled by an electronic battery control system, better known by the acronym BMS (for "Battery Management System" in English) which, for example, controls the battery charging phases to bring the battery to the desired voltage. at the end of recharging without causing excessive heating of the battery and avoiding that one of the cells arrives at a level of charge that is appreciably higher, or appreciably lower, than the other cells of the battery. The BMS system can be configured to calculate a variable without dimensions, such as a state of charge SOC (for State of Charge in English) making it possible to quantify by a variable between zero and 1 the level of charge of the battery.

The BMS system can also be configured to estimate while driving the vehicle, an SOH value (for State of Health in English), which is a coefficient making it possible to quantify the level of energy available in the battery once it is charged. to its full potential, taking into account the degradation of battery performance over its life cycle. The SOH value can be calculated by various methods, and makes it possible to estimate the energy available in the battery at the end of charging and the mileage that the driver can therefore expect to cover.

It is known from document FR-B1-3009093 a method for managing an accumulator battery making it possible to determine with precision the state of aging of a battery fitted to an electric or hybrid vehicle. This process also makes it possible to optimize the management of the battery charging phases according to the calculated aging state. More particularly, in order to improve the lifetime of the battery, the BMS system imposes, at the beginning of the life cycle of the battery, a maximum voltage at the end of recharging which is lower than the maximum acceptable voltage at the end of recharging. The BMS system then increases this maximum voltage over the life cycle of the battery. The purpose of this management of the charging phases is to reduce the aging kinetics according to the use of the battery.

However, when the state of aging of the battery reaches a threshold aging level, the BMS system prohibits any recharging of the battery for security reasons.

The object of the invention is to overcome the drawbacks of the prior art by proposing a method making it possible to increase the duration of use of a battery beyond the threshold aging level.

In this context, the invention thus relates, in its broadest sense, to a method for extending the duration of use of a battery comprising a plurality of cells.

• déterminer une force appliquée sur une paroi d’au moins une cellule de la batterie,
• déterminer un état de charge maximum autorisé de la au moins une cellule en fonction de la force appliquée déterminée.

The method comprises the steps, executed by a computer, of:

• determining a force applied to a wall of at least one cell of the battery,
• determining a maximum permitted state of charge of the at least one cell as a function of the determined applied force.

It should be noted that the more advanced the state of aging of a cell, the greater the force applied to the wall of the latter. When the force applied is too great, the cell is no longer usable. Similarly, the state of charge contributes to the increase in this force. Thanks to the invention, the maximum authorized state of charge is defined as a function of a force applied determined on the wall of the cell. Thus, it is possible for example to reduce the overall force, formed by the determined applied force + the additional force generated by the maximum authorized state of charge, by reducing the maximum authorized state of charge. The invention thus makes it possible to use batteries up to higher aging.

In addition to the characteristics which have just been mentioned in the previous paragraph, the method according to the invention may have one or more additional characteristics among the following, considered individually or in all technically possible combinations.

According to a non-limiting aspect of the invention, the method comprises a step of determining an aging state of the cell, the force applied being determined according to the determined aging state of the cell.

According to a non-limiting aspect of the invention, the maximum authorized state of charge is determined so as to apply to the wall of the cell, an additional force due to an expansion of the cell below a predetermined threshold force – the force applied determined.

According to a non-limiting aspect of the invention, the predetermined threshold force is between 20kN and 30kN.

According to a non-limiting aspect of the invention, the predetermined threshold force corresponds to an aging state of the cell comprised between 60% and 80% of a new state of the cell.

• d'un rapport entre une quantité d’électricité maximum stockable dans la cellule à un instant déterminé et une quantité d’électricité maximum stockable dans la cellule à un état neuf ;
• d’un nombre de recharges de la cellule réalisées ;
• d’une intégration d’un nombre d’heures d’utilisation de la cellule multiplié par un coefficient dépendant d’une température cellule mesurée ; ou
• d’un cumul d’énergie chargée ou déchargée de la cellule.

According to a non-limiting aspect of the invention, the determined state of aging is a function

• a ratio between a maximum quantity of electricity storable in the cell at a determined instant and a maximum quantity of electricity storable in the cell in a new state;
• a number of cell recharges carried out;
• an integration of a number of hours of use of the cell multiplied by a coefficient depending on a measured cell temperature; Or
• of an accumulation of energy charged or discharged from the cell.

Another aspect of the invention relates to a computer arranged to communicate with a battery comprising a plurality of cells, the computer also being arranged to implement the steps of the method according to any one of the aforementioned aspects of the invention. .

The invention and its various applications will be better understood on reading the following description and examining the accompanying figures.

schematically illustrates a lithium-ion type battery module according to a state of the art.

shows, schematically, in particular a control unit of a lithium-ion type battery according to a non-limiting aspect of the invention.

illustrates a step diagram of a non-limiting mode of implementation of the method according to the invention.

shows a graph illustrating the forces applied to a cell of a lithium-ion type battery.

There schematically illustrates a module 1 comprising a battery cell 2, for example of the lithium-ion type. This illustrates for simplification purposes a single cell 2, but it is understood that a module 1 can comprise several battery cells 2.

This cell 2 comprises a wall 3 containing a negative electrode 4 and a positive electrode 5 spaced apart from each other by means of separators 6. This cell 2 also contains an electrolyte 7.

The elements contained in the wall 3, forming an envelope, must be kept in contact within a range of positive force.

To combat the internal pressure which tends to push back the wall 3 of the cell 2, a frame 8, typically made of aluminium, encloses the cells 2, only one of which is visible in the figure.

When using Cell 2, a side reaction occurs. This secondary reaction generates a passivation layer 9 on the surface of the negative electrode 4. This passivation layer 9 is better known as the interphase between the electrolyte and the surface or SEI (for Solid-electrolyte interphase in English) .

This passivation layer 9 increases the volume of the negative electrode 4. This volume increase can reach 4% of the initial volume of the cell 2.

During this secondary reaction, gases are also produced which contribute to an increase in the internal pressure of cell 2 which, for safety reasons, must remain perfectly sealed. This pressure can reach 6 bars.

The more advanced the state of aging of cell 2, the greater the force exerted on wall 3 of cell 2. The state of aging of a cell is therefore very strongly linked to the force applied to the wall 3 of the cell 2 generated by its expansion.

There illustrates a computer 10, for example formed by a battery control unit 11 comprising a plurality of cells 2. This battery control unit 10 is better known under the name BMS (for “Battery Management System”).

In this non-limiting embodiment, the cells 2 are contained in a frame 8 and together form a module. The battery 11 can comprise several modules.

The battery control unit 10 communicates with a control unit 12 of an electric motor 13 and an electric charger 14.

Thus, the battery control unit 10 is arranged to authorize or not the recharging of the cells 2 of the battery 11.

The battery control unit 10 is arranged to implement the steps of a method for extending a duration of use of a battery according to the invention.

There shows a diagram of steps of an embodiment of the method 100 according to the invention.

The steps of the method 100 are executed by a computer such as, for example, the battery control unit 10 shown in .

The implementation of the different steps of the method 100 is also illustrated in support of the .

More specifically, the illustrates a force applied in kN to the wall 3 of a cell 2 as a function of a state of aging SOHc in percent.

A first curve C1 illustrates a force applied to the wall 3 of a cell 2 as a function of an aging state SOHc of cell 2 + a state of charge of 0%. The state of charge is a state of charge of the SOC type (for State Of Charge in English).

A second curve C2 illustrates a force applied to wall 3 of cell 2 as a function of an aging state SOHc of cell 2 + a maximum authorized state of charge SOC of 100%.

A third curve C3 illustrates a force applied to wall 3 of cell 2 as a function of a state of aging SOHc of cell 2 + a variation of a state of charge SOC between 0% and 100%.

A fourth curve C4 illustrates a curve representing a variation of a maximum state of charge SOC in percent.

The method 100 includes a step, executed by the battery control unit 10, of determining 101 an aging state of at least one cell 2.

In a non-limiting embodiment, the state of aging can be formed by a SOHc “for State of Health capacity in English”. Such a state of aging reflects the number of ampere/hours that cell 2 can store at a given time.

• d'un rapport entre une quantité d’électricité maximum stockable dans la cellule 2 à un instant déterminé et une quantité d’électricité maximum stockable dans la cellule 2 à l’état neuf,
• d’un nombre de recharges de la cellule 2 réalisées,
• d’une intégration d’un nombre d’heures d’utilisation de la cellule 2 multiplié par un coefficient dépendant d’une température cellule mesurée par un capteur de température, ou
• d’un cumul d’énergie chargée ou déchargée de la cellule 2.

The determined state of aging of cell 2 can for example be a function of:

• a ratio between a maximum quantity of electricity storable in cell 2 at a given time and a maximum quantity of electricity storable in cell 2 when new,
• a number of cell 2 recharges carried out,
• an integration of a number of hours of use of cell 2 multiplied by a coefficient depending on a cell temperature measured by a temperature sensor, or
• of an accumulation of energy charged or discharged from cell 2.

The method 100 includes a step, executed by the battery control unit 10, of determining 102 a force applied to the wall 3 of the cell 2.

In a non-limiting implementation, the force applied is determined according to the state of aging of the cell 2 determined during the previous step 101.

Indeed, during the use of cell 2, a secondary reaction occurs generating a passivation layer 9 on the surface of the negative electrode 4 of cell 2. This passivation layer 9 increases the volume of the electrode negative 4 and generates an increase in the force applied to the wall 3 of the cell 2. This increase in volume, and therefore the increase in the force applied to the wall 3 of the cell 2, is irreversible and is linked to its state SOHc aging.

The method 100 comprises a step, executed by the battery control unit 10, of determining 103 a maximum authorized state of charge of the cell 2 according to the determined applied force.

The maximum authorized state of charge is determined so as to apply to the wall 3 of the cell 2 an additional force due to an expansion of the cell 2 less than or equal to a predetermined threshold force – the determined applied force.

When a force greater than the threshold force is applied to the wall 3 of the cell 2, it is forbidden to use the battery 11 containing it. Indeed, beyond this threshold force, cell 2 risks breaking or catching fire.

In the non-limiting example illustrated in , the threshold force is 25kN.

Thus, in this exemplary embodiment, from a determined applied force of 20kN, corresponding to an SOHc aging state of 20% of cell 2, the maximum authorized state of charge (curve C4) is reduced so as to that the determined applied force due to the state of aging of cell 1 (curve C1) + the additional force due to the expansion applied to wall 3 of cell 2 due to the maximum authorized load state do not exceed together the threshold force of 25kN.

The battery control unit 10 thus limits the battery recharge current coming from the electric motor 13 or from the charger 14 by transmitting current limitation information to the controller 12.

This non-limiting implementation makes it possible to extend the use of the cell 2 and therefore of the battery 11 beyond the 80% state of aging thanks to the limitation of the maximum authorized state of charge SOC. Indeed, this reduction, illustrated by the fourth curve C4, of the maximum authorized state of load SOC from 20 kN, allows, although the state of aging SOHc is at an advanced stage, to limit the overall force (curve C2), formed by the force due to the state of aging + the force due to the maximum authorized state of charge SOC, applied to the wall 3 of the cell 2 below the critical threshold of 25kN in the example.

Without this reduction, it can be seen on the dotted part of the second curve C2 that the overall force applied to the wall 3 of the cell 2, function of the force due to the state of aging SOHc of the cell 2 and of that due to the maximum authorized state of charge SOC would exceed the threshold force of 25kN. Such a situation would not be acceptable. Thus, battery 11 would no longer be used as soon as 20% of the SOHc aging state would have been reached.

It should be noted that those skilled in the art are able to make different variants to the aforementioned aspects of the invention, for example by modifying the value of the threshold force.

Claims (10)

Method (100) for extending a duration of use of a battery (11) comprising a plurality of cells (2), said method (100) being characterized in that it comprises the steps, executed by a computer (10), of:

• determining (102) a force applied to a wall (3) of at least one cell (2) of said battery (11),
• determining (103) a maximum authorized state of charge (SOC) of said at least one cell (2) as a function of said determined applied force.

Method (100) according to the preceding claim, characterized in that it includes a step of determining (101) a state of aging (SOHc) of the cell (2), said determined applied force being determined as a function of said state of aging (SOHc ) of said cell (2) determined. Method (100) according to any one of the preceding claims, characterized in that the maximum authorized state of charge (SOC) is determined so as to apply to the wall (3) of the cell (2) an additional force due to a expansion of said cell (2) less than a predetermined threshold force - the determined applied force. Method (100) according to the preceding claim, characterized in that the predetermined threshold force is between 20kN and 30kN. Method (100) according to Claim 3 or 4, characterized in that the predetermined threshold force corresponds to a state of aging (SOHc) of the cell (2) of between 60% and 80% of a new state of the cell (2 ). Method (100) according to Claim 2, characterized in that the determined state of aging is a function of a ratio between a maximum quantity of electricity storable in the cell (2) at a determined moment and a maximum quantity of electricity storable in the cell (2) to new condition. Method (100) according to Claim 2, characterized in that the determined state of aging is a function of a number of recharges of the cell (2) carried out. Method (100) according to Claim 2, characterized in that the state of aging determined is a function of an integration of a number of hours of use of the cell (2) multiplied by a coefficient depending on a cell temperature measured. Method (100) according to Claim 2, characterized in that the determined state of aging is a function of an accumulation of energy charged or discharged from the cell (2). Computer (10) arranged to communicate with a battery (11) comprising a plurality of cells (2), said computer (10) being characterized in that it is further arranged to implement the steps of the method (100) according to any of the preceding claims.