WO2019175498A1 - Battery with optimised life - Google Patents

Abstract

Method (100) for managing a battery (1) for storing electrical energy, wherein the battery (1) is arranged to operate alternately in a first configuration, or in a second configuration, the battery (1) further comprising an electronic unit (4) configured to implement the following steps during a first period of operation of the battery (1) in the first configuration: controlling at least one means for measuring the battery so as to perform a measurement (101) of at least one value of at least one operating parameter of the battery; determining (102) the end of the first period of operation according to the at least one measured value for the at least one operating parameter; communicating (103) the end of the first period of operation determined in the preceding step, the management method comprising a phase of use (200) of the battery during a second period of operation subsequent to the first period of operation, in which the battery adopts the second configuration.

Description

 Battery with optimized life

 The present invention relates to the field of DC batteries, and more particularly batteries with optimized lifetime.

The very important development of the electric mobility market in particular, stimulates research aimed at optimizing the life of batteries. A battery designed for electromobility is usually considered to have reached the end of its life when it has lost 20% of its original capacity. However, a battery that still retains 80% of its initial capacity, should still be able to serve secondary uses, even if it is no longer suitable for electromobility, its first use. On known batteries, no provision is provided to facilitate a second life of these batteries; the owner of batteries designed for electromobility has the choice between two options: either to entrust its batteries to a recycling system, or to repackage its batteries for a new use, this second option being expensive and not economically viable.

The invention therefore aims to provide a simple solution to all or part of these problems.

 For this purpose, the present invention relates to a method for managing an electric energy storage battery, in which the battery is arranged to operate alternately:

 in a first configuration, or

 in a second configuration,

 the battery further comprising an electronic unit configured to implement the following steps during a first period of operation of the battery in the first configuration:

controlling at least one means for measuring the battery so as to measure at least one value of at least one operating parameter of the battery, determining the end of the first operating period as a function of the at least one measured value for the at least one operating parameter,

 communicate the end of the first operating period determined in the previous step,

the management method comprising a phase of using the battery during a second period of operation subsequent to the first period of operation, wherein the battery adopts the second configuration.

According to one embodiment, the first configuration is adapted to a first use which requires performance of the battery, during the first period of operation, greater than its use during the second period of operation; the second configuration of the battery provides other functions adapted to the constraints of the second period of operation.

Thanks to these arrangements, from a moment determined automatically by the battery in the determination step, a new operating period can begin, during which the user can operate the battery in the second configuration in a remote environment. different use for the operation of the battery. An example of a first use in mobility, having mechanical, vibration, shock and temperature constraints different from a second stationary use, for example a domestic interior environment, requiring a more precise thermal management, which will result in to increase the life of the battery.

According to one embodiment, the battery comprises a plurality of electric energy storage cells, and wherein the at least one measurement means comprises at least one of:

means for measuring a number of charge and discharge cycles for the plurality of cells, a means of measuring a health indicator of the piacity of cells,

 means for measuring an electric current,

 means for measuring a voltage,

 a means for measuring an electric power supplied by each cell of the plurality of cells, and by the plurality of cells, a means for measuring a mechanical shock indicator and for counting a number of mechanical shocks suffered by the battery, a means of measuring a humidity level in the battery,

 means for measuring one or more temperatures of the plurality of cells, or a temperature gradient,

 means for measuring a balancing time of each cell, means for measuring a number of critical events, and wherein at least one operating parameter of the battery comprises at least one of the parameters among the following parameters:

 a number of cycles of charges and discharges,

 an indicator of the state of health of the plurality of cells,

 a maximum voltage supplied by the plurality of cells, a minimum voltage supplied by the plurality of cells, - a maximum voltage supplied by each cell of the plurality of cells,

 a minimum voltage supplied by each cell of the plurality of cells,

 a maximum charge electric current supplied by the plurality of cells,

a maximum discharge electric current provided by the cell density, a maximum of the average discharge electric current supplied by the plurality of cells,

 a maximum of the average electric discharge power provided by the plurality of cells,

- a duration of use under load, a duration of use in discharge,

 a valid end of charge number,

 a valid end of discharge number,

 a number of interruption of operation,

- balancing time of each cell of the plurality of cells,

 a temperature shock indicator of the plurality of cells, a minimum temperature of each cell of the plurality of cells, in operation or out of operation,

 a maximum temperature of each cell of the plurality of cells, in operation or out of operation,

 a minimum temperature of the plurality of cells, in operation or out of operation,

 a maximum temperature of the plurality of cells, in operation or out of operation,

a maximum temperature gradient for each cell of the plurality of cells,

 a duration of use between a first temperature and a second temperature,

 a number of cycles since the last update of the value of the battery capacity

 a number of critical events,

the total energy input and output of the battery. According to one embodiment, the at least one operating parameter of the battery comprises:

 a number of charge / discharge cycles,

 an indicator of the state of health of the plurality of cells, and the determining step consists in determining the beginning of a new operating period if the value of the indicator is greater than 80% and if the value of the number of charge / discharge cycles is greater than 1000.

According to one embodiment, the method further comprises a final phase (201) of battery reform is implemented if the value of the health status indicator of the plurality of cells is greater than 80% and if the value of the number of charge / discharge cycles is less than 100.

According to one embodiment, if the determining step determines that the health status indicator value of the plurality of cells is greater than 80% and the value of the number of charge / discharge cycles is less than at 100, the battery can not be used in a subsequent period. The battery will need to be recycled.

In another aspect, the invention also relates to a battery comprising:

 a first structure comprising a plurality of electric energy storage cells, the plurality of cells being arranged for a flow of air to flow freely around and between the cells of the plurality of cells,

a second structure comprising an envelope configured to be removably mounted on the first structure; the battery being arranged to operate alternately: in a first configuration comprising the first structure and the envelope covering the first structure, or

 in a second configuration comprising the first structure without the envelope, or the first structure and only part of the envelope partially covering the first structure;

 the battery further comprising an electronic unit and at least one measuring means, the electronic unit being configured to control said at least one measuring means and to carry out the steps of the method according to one of the preceding claims, during a first period of operation of the battery in the first configuration.

According to one embodiment, the electronic unit comprises:

 a measurement module, configured to measure at least one value of at least one operating parameter of the battery, a processing module, configured to determine an end of a period of time, according to the at least one measured value for the at least one operating parameter, a communication module, configured to communicate the end of its period of time determined in the previous step.

According to one embodiment, the at least one measurement means comprises at least one of:

 means for measuring a number of charge and discharge cycles for the plurality of cells,

 a means of measuring a health indicator of the plurality of cells

 means for measuring an electric current,

means for measuring a voltage, means for measuring an electrical power supplied by each cell of the plurality of cells, and by the plurality of cells, a means for measuring a mechanical shock indicator and for counting a number of mechanical shocks suffered by the battery, a means for measuring a humidity level in the battery, a means for measuring a temperature of each cell of the plurality of cells, or a temperature gradient, a means of measuring a duration balancing each cell of the plurality of cells,

 a means for measuring a number of critical events.

According to one aspect of the invention, the first structure comprises a first branch interface adapted to the environment of use during the period of operation, the battery further comprising a connector adapter configured to be connected to the branch interface and provided with a second branch interface adapted to the new environment of use after the end of the period of operation.

Thanks to these provisions, it is easy to integrate the battery, which was defined to operate in a first configuration adapted to a first environment of use, to a new environment of use, characterized by a different connectivity.

For a good understanding, the invention is described with reference to the accompanying drawings showing, by way of non-limiting example, an embodiment of a device according to the invention.

Figure 1 shows schematically the battery in its envelope. Figure 2 is a perspective view of the envelope of the battery.

Figure 3 is a perspective view of the battery core, with a plurality of elementary storage cells.

Figure 4 is a schematic representation of the battery with its connection interface and a connector adapter.

Figure 5 is a schematic representation of the process.

 In the following detailed description of the figures, the same elements or elements fulfilling identical functions may retain the same references so as to simplify the understanding of the invention.

According to an embodiment of the method 100 according to the invention, the method 100 is a method of managing a battery 1 for storing electrical energy. The battery 1 is primarily intended, in a first configuration, for a given use, for example on electric mobility applications; the battery 1 is intended, as a secondary application, in a second configuration, to a less intensive use, for example in a stationary indoor application in a home environment.

The method 100 is primarily intended to monitor the state of health of the battery during its first use in the first configuration, so as to determine the appropriate time to move from the first mobility application to the second stationary application. As is illustrated in FIGS. 1, 2 and 3, the battery 1 for storing electrical energy is generally provided with a core constituted by a plurality of elementary cells 11 for storing electrical energy, and a mechanical system to ensure the battery mechanical robustness adapted to the constraints related to the mobility of the first use. During this first period of use, the battery must indeed withstand vibration, shock, and moisture, while remaining portable.

The constraints specific to the second stationary use are different: thermal environment, connectors, specific mechanical integration.

Thus, the mechanical system of a battery according to the invention comprises:

 A first structure 2 for supporting the constraints of the stationary application, including cooling and specific connectivity; this first structure 2 comprises in particular the core consisting of the plurality of cells 11 which provides the main function of storing the electrical energy.

 The first structure 2 has, on the other hand, the cooling characteristics enabling it to let a heat-transfer fluid pass between the cells 11, in the form of, for example, an air flow (by natural or forced convection), and makes it possible to respond standard battery standards (shock, vibration, overvoltage, over-current, short circuit, excessive temperature ...).

A second structure 3, of the additional protective envelope type, configured to be removably mounted on the first structure, to protect it from the constraints of the mobility application: envelope for protection against shocks, humidity and vibrations .

The envelope can be provided with a handle to allow improved portability. The protective casing 3 has the characteristics of resistance to direct impact and splashing water: typically, it is formed of an extruded part made of aluminum or plastic or thermoformed or injected plastic panels. For disassembly, these parts are easily connected using conventional screws, or a rail attachment system, integrated in the first structure for fixing the second structure, and for insertion into the application stationary.

Thus, the protective envelope 3 provides protection adapted to most environments, IP65 or IP67 protection for example for outdoor environments, during the first period of use in the first configuration.

During the second period of use, in a less restrictive environment, for example indoors, the removal of the protective envelope 3 facilitates the removal of heat, harmful for the life of the battery and produced by the cells 11 during operation, and thus to increase the life of the battery.

On the other hand, to monitor the various indicators of the state of health of the battery during a first period of use in the first configuration, the battery 1 further comprises an electronic unit 4 and at least one means of measuring, the electronic unit 4 being configured to control said at least one measuring means and to implement the steps of the method 100 according to one of the embodiments of the invention.

Thus, to better know the aging characteristics of the battery and to decide the optimal date of change of life, the on-board electronic unit may be of the battery management system (BMS) type. To take into account the constraints of the two types of application, the electronic unit 4 controls the measurement, by the at least one measuring means, of at least one of the following operating parameters:

 number of charge and discharge cycles,

 indicator of the state of health of the plurality of cells,

 maximum voltage supplied by the plurality of cells, minimum voltage provided by the plurality of cells, maximum voltage supplied by each cell,

 minimum voltage provided by each cell, - maximum voltage gradient provided by each cell, maximum load current supplied by the plurality of cells,

 maximum discharge electric current supplied by the plurality of cells,

 maximum of the average discharge electric current supplied by the plurality of cells,

 maximum of the average electrical discharge power provided by the plurality of cells,

 duration of use under load,

 - duration of use in landfill,

 valid end of charge number,

 number of valid end of discharge,

 number of interruption of operation,

balancing time of each cell of the plurality of cells, a temperature shock indicator of the plurality of cells, minimum temperature of each cell of the plurality of cells, in operation or out of operation,

 maximum temperature of each cell of the plurality of cells, in operation or out of operation,

 - minimum temperature of the plurality of cells, in operation or out of operation,

 maximum temperature of the plurality of cells, in operation or out of operation,

 maximum temperature gradient for each cell of the plurality of cells,

 duration of use between a first temperature and a second temperature,

 number of cycles since the last update of the value of the battery capacity,

 - number of critical events,

 the total energy input and output of the battery.

The processing of the various information thus monitored by the electronic unit 4 makes it possible to choose the passage to the second life or the end of life.

For example, the decisive parameters for deciding on the transition from the first use to the second use can be:

 the number of charge and discharge cycles,

the health status indicator of the plurality of cells, and the decision criterion may be as follows: if the value of the indicator is greater than 80% and the value of the number of charge / discharge cycles is greater than 1000, then the battery can and must go to the next use phase, according to the second configuration. Another example of a decision criterion concerning a non-reusable battery is as follows: if the value of the health status indicator of the plurality of cells is greater than 80% and the value of the number of charge cycles / discharges is less than 100, so the battery needs to be reformed and recycled.

Advantageously, on a battery configured to provide a nominal voltage of 56 volts, the control unit can be configured to monitor the following parameters:

 maximum voltage supplied by the plurality of cells, which must remain below 60 volts;

 - minimum voltage provided by the plurality of cells, which must remain greater than 20 volts;

 maximum voltage supplied by each cell, which must remain below 4.2 volts;

 minimum voltage provided by each cell, which must remain above 2.5 Volts;

 health status indicator of the plurality of cells, which must remain greater than 80%;

 maximum charge electric current provided by the plurality of cells, which must remain less than 5 Amperes;

 - maximum discharge electric current provided by the plurality of cells, which must remain less than 20 amperes;

 maximum gradient of electrical voltage supplied by each cell, which must remain below 15 degrees Celsius;

 temperature of the plurality of cells, in operation, which must remain between 0 degrees Celsius and 50 degrees Celsius;

 temperature of the plurality of cells, out of operation, which must remain between -20 degrees Celsius and 60 degrees Celsius;

number of critical events, shocks for example, which must remain less than 1; If any of these criteria are not met, the battery must be sent for further diagnosis or recycling.

 The implementation of a communication system directly integrated in the electronic card allows a regular monitoring (near distance communication, Bluetooth type, Lora, Zigbee, ...} or continuous (remote communication type GSM) to allow to put implement a change of life or an end of life in an optimal way.

 Thus, the management method 100 according to the invention, as schematically illustrated in FIG. 5, thus comprises the following steps:

 to control at least one means for measuring the battery so as to make a measurement 101 of at least one value of at least one operating parameter of the battery,

 determining the end of the first operating period as a function of the at least one measured value for the at least one operating parameter,

 communicate 103 the end of the first operating period determined in the previous step,

the management method 100 comprising a use phase 200 of the battery during a second period of operation subsequent to the first period of operation, wherein the battery adopts the second configuration.

 According to an embodiment of the management method 100 of the battery 1, the method may also include a final phase 201 of battery reform, final phase implemented when certain operating parameters indicate that the battery is no longer able to work properly, even in a stationary environment and in the second configuration.

Finally, to facilitate the transition from the first to the second use, the invention also relates to a connector adapter 5, illustrated in Figure 4, which allows to integrate a simple and fast way a battery designed for a first use with a special connectivity 6, 7 in a second application requiring a specific connection 10. The adapter 5 has two female plugs 8, 9, each female plug being configured to cooperate with a corresponding male plug 6, 7 of the particular connector, the adapter being configured to ensure the transformation of the connector 6.7 adapted to the first use, a connector 10 adapted to the second use. The male plugs 6, 7 and the corresponding sockets 8, 9 are, for example, configured for the transport of signals, respectively of electrical power, and communication, to the plugs 10 of the connectors for the second application.

Claims

 A method (100) for managing a battery (1) for storing electrical energy, wherein the battery (1) is arranged to operate alternately:

 in a first configuration, or

 in a second configuration,

 the battery (1) further comprising an electronic unit (4) configured to carry out the following steps during a first period of operation of the battery (1) in the first configuration:

 controlling at least one means for measuring the battery so as to perform a measurement (101) of at least one value of at least one operating parameter of the battery,

 determining (102) the end of the first operating period as a function of the at least one measured value for the at least one operating parameter,

 - communicate (103) the end of the first operating period determined in the previous step,

the management method comprising a phase of use (200) of the battery during a second period of operation subsequent to the first period of operation, wherein the battery adopts the second configuration.

The method (100) of claim 1, wherein the battery (1) comprises a plurality of electrical energy storage cells, and wherein the at least one measuring means comprises at least one of the means :

 means for measuring a number of charge and discharge cycles for the plurality of cells,

 means for measuring a health indicator of the plurality of cells,

 means for measuring an electric current,

means for measuring a voltage, means for measuring an electrical power supplied by each cell of the plurality of cells, and by the plurality of cells, means for measuring a mechanical shock indicator and for counting a number of mechanical shocks to the battery, a means for measuring a humidity level in the battery, a means for measuring one or more temperatures of the plurality of cells, or a temperature gradient,

 means for measuring a balancing time of each cell, a means for measuring a number of critical events,

and wherein the at least one operating parameter of the battery comprises at least one of the following parameters:

 a number of cycles of charges and discharges,

 an indicator of the state of health of the plurality of cells,

 a maximum voltage supplied by the plurality of cells, a minimum voltage supplied by the plurality of cells, a maximum voltage supplied by each cell of the plurality of cells,

 a minimum voltage supplied by each cell of the plurality of cells,

 a maximum charge electric current supplied by the plurality of cells,

 a maximum discharge electric current supplied by the plurality of cells,

a maximum of the average discharge electric current supplied by the plurality of cells, a maximum of the average electric discharge power provided by the plurality of cells,

 a duration of use in charge,

 a duration of use in landfill,

a valid end of charge number,

 a valid end of discharge number,

 a number of interruption of operation,

 balancing time of each cell of the plurality of cells, a temperature shock indicator of the plurality of cells, - a minimum temperature of each cell of the plurality of cells, in operation or out of operation,

 a maximum temperature of each cell of the plurality of cells, in operation or out of operation,

 a minimum temperature of the plurality of cells, in operation or out of operation,

 a maximum temperature of the plurality of cells, in operation or out of operation,

 a maximum temperature gradient for each cell of the plurality of cells,

a duration of use between a first temperature and a second temperature,

 a number of cycles since the last update of the value of the battery capacity

 a number of critical events,

the total energy input and output of the battery.

3. Battery (1) for storing electrical energy, the battery (1) comprising:

 a first structure (2) comprising a plurality of electric energy storage cells, the plurality of cells being arranged for a flow of air to circulate freely around and between the cells of the plurality of cells,

 a second structure (3) comprising an envelope configured to be removably mounted on the first structure;

 the battery (1) being arranged to operate alternately:

 in a first configuration comprising the first structure and the envelope covering the first structure, or

 in a second configuration comprising the first structure without envelope, or the first structure and only part of the envelope partially covering the first structure;

 the battery (!) further comprising an electronic unit (4) and at least one measuring means, the electronic unit (4) being configured to control said at least one measuring means and to carry out the steps of the method ( 100) according to one of the preceding claims, during a first period of operation of the battery (1) in the first configuration.

4. Battery {1} for storing electrical energy according to the preceding claim, wherein the first structure comprises a first branch interface (6,7) adapted to the environment of use during the period of operation, the battery comprising in addition a connector adapter (5) configured to be connected to the connection interface (6,7) and provided with a second branch interface (10) adapted to the new environment of use after the end of the operating period .