EP4038686A1

EP4038686A1 - Method for avoiding the spread of a thermal event in an enclosure containing several modules of electrochemical elements

Info

Publication number: EP4038686A1
Application number: EP19941781.7A
Authority: EP
Inventors: Gilles Helschger; Christophe Le Guern; Jean-Louis Liska; Christophe Morin
Original assignee: SAFT Societe des Accumulateurs Fixes et de Traction SA
Current assignee: SAFT Societe des Accumulateurs Fixes et de Traction SA
Priority date: 2019-10-03
Filing date: 2019-10-03
Publication date: 2022-08-10
Also published as: US20220336882A1; WO2021064298A1; CN114730923A

Abstract

A method for avoiding the spread of a thermal event in an enclosure containing several modules (1, 2, 3, 4) of electrochemical elements, said method comprising the following steps: - detecting one or more critical modules (1, 2, 3) situated in the enclosure, and affected by a thermal event (13), a module being critical when one or more parameters associated with the status of the module have reached or crossed a predetermined threshold, - spraying a coolant (12) onto, or into, the critical module or modules (1, 2, 3) for a determined duration and/or at a determined flow rate, one or more modules (4) not detected as being critical modules not receiving any coolant (12).

Description

Method for preventing the propagation of a thermal event in an enclosure comprising several modules of electrochemical elements

TECHNICAL AREA

The invention relates to the technical field of methods for preventing the propagation of a thermal event in an enclosure comprising several modules of electrochemical elements.

STATE OF THE ART

A battery module, also referred to in what follows by the term "module", is known from the state of the art. It generally comprises several electrochemical elements, also designated in what follows by the term “elements”, electrically connected to each other, in series or in parallel, by means of metal bars. These metal bars have a sufficient section to allow the flow of high intensity currents between the elements of the module. The module also generally comprises an electronic circuit for controlling and managing the elements, intended to measure their state of charge and / or their state of health, in particular by means of voltage or current measurements taken individually element by element or taken on a device. group of elements. The module can also include a device for regulating its temperature.

Several battery modules can be connected together in series and / or in parallel and installed in a bay, also called a “rack”. The dimensions of the bay are generally standardized. For example, a bay may have a standard width of 48.26 cm (19 inch bay). This bay constitutes an electrochemical storage unit, also called “Electrochemical Storage System Unit (ESSU)”. Several bays can be connected in parallel in order to increase the amount of electrical energy. All the bays can be stored in a room of a building or in a transport container. The transport container can be moved and installed near renewable energy sources, such as photovoltaic cells or wind turbines. It stores the electricity generated by these energy sources and returns it as a power supply to electrical or electronic systems. The container bears the name of the electrochemical storage system “Electrochemical Storage System or Energy Storage System (ESS)”. An element of a module of a bay installed in an electrochemical storage system may experience an operating fault. This anomaly can be caused by an internal short-circuit in the element, or by an external disturbance (shock, temperature rise) or even by a failure of the electronic control and management circuit of the element. This anomaly can cause it to heat up. This heating can in turn lead to an increase in the charging current which further promotes an increase in the temperature of the element. If the malfunctioning element is not sufficiently cooled, it finds itself in a situation of thermal runaway, that is to say that the increase in temperature is maintained by the element itself. The uncontrolled increase in the temperature of an element results in the generation of gases and their expansion inside the element's container. This expansion causes an increase in the internal pressure in the element, which will cause the opening of a gas evacuation safety system. In the event of the release of hot gases, the temperature of which can reach 650 ° C., these gases come into contact with the other elements housed in the module. There is then a risk that the thermal runaway phenomenon spreads to all of the elements of the module, then to all of the modules of a bay, and finally to all of the bays of the electrochemical storage system. If no way exists to prevent the runaway from spreading, the entire electrochemical storage system can be destroyed.

One way to reduce the risk of thermal runaway propagation from one element of a module to another element of the module consists in providing sufficient space between these elements or to install between these elements a material acting as a thermal barrier. . However, this solution requires providing sufficient space between the elements and leads to the production of bulky modules. It therefore penalizes the energy density of the module.

Another way is to use a Fire Suppression System (FSS). Such a system projects a fire extinguishing agent onto the module (s) in a thermal runaway situation. It typically uses a coolant which is liquid carbon dioxide or liquid nitrogen.

Document EP-A-1 168 479 describes a battery comprising a box in which eight electrochemical elements of the lithium-ion type are housed. When an element heats up and its temperature exceeds a limit value, a pyrotechnic device is triggered and commands the opening of a reservoir containing an extinguishing agent. The extinguishing agent is released in the trunk for the purpose of cooling the battery. In this document, the elements are all cooled by the extinguishing agent regardless of their distance from the element in a situation of thermal runaway.

Document CN 106684499 describes a method for stopping thermal runaway in a battery comprising lithium-ion cells / modules. The battery includes a box in which the cells / modules are housed. A tank filled with fire extinguishing agent is placed in the trunk. A hose is connected at one end to the tank. The pipe is provided with a plurality of nozzles evenly distributed along the length of the pipe. These nozzles spray the extinguishing agent over the elements / modules.

The method described in this document does not achieve a differentiated treatment of the modules depending on whether they are located near the thermal runaway initiator module or whether they are far from the thermal runaway initiator module. An element / module remote from the element / module initiating thermal runaway is sprayed with extinguishing agent in the same manner as the element / module initiating thermal runaway. Furthermore, in this document the element / module in a thermal runaway situation is sprayed with extinguishing agent in order to stop the thermal runaway. However, it turns out that the sprinkling of an extinguishing agent on a lithium-ion type element / module already in a situation of thermal runaway is inefficient, because a very large amount of energy is stored in a lithium-ion type element / module. The amount of energy released in the form of heat upon opening the element / module container is so great that the extinguishing agent flow rate is usually insufficient to neutralize the rise in temperature, this enormous amount. energy being released suddenly over a short period of time. If the module's thermal runaway is not controlled, it spreads to neighboring modules and can lead to complete destruction of the battery.

In addition, known fire extinguishing systems are not totally effective because the propagation of thermal runaway is not only due to the propagation of flames from one element to another but also due to the propagation of the heat. heat by convection and conduction from one element to another. The propagation of heat by conduction is explained by the presence of the metal bars of the power circuit of the elements of the module and also by the presence of electronic circuits for managing the state of charge and the state of health of the elements of the module. module. These metal components promote the transmission of heat from one element to another. In addition, conventional fire extinguishing systems are generally inefficient due to the fact that thermal runaway occurring in a module leads to overpressure in the module shell, due to the release of gases. This overpressure prevents the extinguishing agent from entering the enclosure of the module and acting effectively.

There is therefore a need for a method which makes it possible to avoid, in the event of the occurrence of a thermal runaway or of any other event generating a sudden increase in temperature in one or more modules of an enclosure, that this thermal event does not propagate to other modules arranged in this enclosure.

There is also a need for a method which makes it possible to prevent the propagation of a thermal event by thermal conduction between the modules of the enclosure.

There is also a need to limit the risk of restarting a thermal event for a long period of time, after having contained / mastered a first thermal event.

SUMMARY OF THE INVENTION

Thus, the subject of the invention is a new method for preventing the propagation of a thermal event in an enclosure comprising several modules of electrochemical elements, said method comprising the following steps: detection of one or more critical modules placed in the chamber. enclosure, affected by a thermal event, a module being critical when one or more parameters related to the state of the module have reached or exceed a predetermined threshold, diffusion of a cooling agent on, or in, the critical module (s) , for a period and / or at a determined rate, one or more modules which are not detected as critical modules not receiving cooling agent.

The thermal event may have been initiated by one or more modules of the enclosure or may have been initiated in a location of the enclosure not occupied by one or more modules. The thermal event can be a thermal runaway in one or more modules of the enclosure, for example due to the occurrence of an internal short-circuit in an element of a module. The thermal event can also be the start of a fire in the enclosure, without necessarily that this fire was caused by the occurrence of thermal runaway of a module. The thermal event can also be an overheating of one or more several modules, which overheating may be caused by a malfunction of the module cooling system. The overheating can also be caused by a malfunction of the air conditioning system of the enclosure or by a malfunction of the charging device of the modules which has led to an overload of one or more modules. More generally, the thermal event can be any increase in temperature in a location of the enclosure, which has the effect of raising the temperature of one or more modules beyond the maximum value of their nominal operating range. .

The invention is based on the discovery that it is possible to prevent the propagation of a thermal event by cooling the module or modules liable to be affected by a thermal event which has occurred in one or more other given modules of the enclosure or occurred in a location of the enclosure not occupied by one or more modules. By diffusing a cooling agent in or on the modules likely to be affected by the thermal event, it is possible to maintain the temperature of these modules at a value below a threshold value beyond which they would in turn risk to be subject to a thermal event. Thus, it is possible to prevent a thermal event which initially occurred in one or more given modules or which occurred in a location of the enclosure not occupied by one or more modules, from being the cause the start of new thermal events.

The invention is based on the discovery that it is preferable to cool the modules adjacent to the module (s) subject to a thermal event or adjacent to the location of the enclosure in which the thermal event occurred, rather than attempt to extinguish the module fire in a thermal event situation.

The method according to the invention solves the problem of the propagation of heat by thermal conduction between one or more given modules.

According to one embodiment, said parameter or parameters include the temperature inside the module or modules, one or more modules being considered critical when the temperature of the module or modules exceeds a predetermined threshold value Ts.

According to one embodiment, said parameter (s) comprise the presence of smoke and / or gas inside the module (s), one or more modules being considered critical when the concentration of smoke and / or gas exceeds a predetermined value. .

According to one embodiment, in the event of a thermal event initiated by one or more modules of the enclosure, the duration and / or the flow rate are determined so that the temperature of the or critical modules is kept below a threshold temperature Tmax, with the exception of the module (s) initiating the thermal event.

According to one embodiment, the determined duration is greater than or equal to 1 hour, preferably greater than or equal to 2 hours and, preferably, less than or equal to 12 hours.

According to one embodiment, the cooling agent is a compound whose cooling effect is mainly obtained by the transition from a liquid phase to a gas phase, in particular a water mist or carbon dioxide or water. 'nitrogen.

According to one embodiment, each module comprises an envelope having an external surface and the diffusion of the cooling agent is carried out on said external surface.

According to one embodiment, each module comprises an envelope delimiting an internal volume in which electrochemical elements are housed, and the cooling agent is diffused by injection into said internal volume.

According to one embodiment, the cooling agent is stored in liquid form in a reservoir.

According to one embodiment, the detection of one or more critical modules is carried out by means of one or more detectors arranged in, on or near each module of the enclosure, the detector or detectors being a threshold detector. temperature and / or a temperature sensor and / or a smoke or gas detector.

According to one embodiment, when the detector detects one or more critical modules, the diffusion of the cooling agent on, or in, the critical module or modules is triggered immediately or delayed.

According to one embodiment, when the detector detects one or more critical modules, it sends a signal to a central device which controls the diffusion of the cooling agent on, or in, the critical module or modules.

The subject of the invention is also an installation for implementing the method as described above, said installation comprising several modules of electrochemical elements, each module being equipped with detection means capable of detecting whether the module is a module. critical affected by a thermal event, a module being critical when one or more parameters related to the state of the module have reached or exceed a predetermined threshold, the installation comprising diffusion means, for a period and / or at a rate determined, of a cooling agent on, or in, the critical module (s) detected by the detection means, one or more modules which are not detected as critical by the detection means not receiving cooling agent.

According to one embodiment, the installation comprises means for controlling the diffusion rate, the cooling agent being a water mist, and the means for controlling the diffusion rate being configured so that the rate determined by critical module or between 0.1 and 2 kg / h per kWh of electrical energy stored in the critical module.

According to one embodiment, the diffusion means comprise a reservoir, a distribution network, and a plurality of diffusion devices arranged on, in, or near respectively each module of the enclosure, the cooling agent being stored. in the reservoir, the reservoir being connected to the diffusion devices via the distribution network.

According to one embodiment, the diffusion means comprise a central device for controlling the diffusion of the cooling agent, configured to receive a signal, emitted by the detection means, and to trigger the diffusion of the cooling agent. on, in or near critical modules upon receipt of a thermal event detection signal.

FIGURES

Figure 1 is a schematic representation of the installation according to the invention.

Figure 2 is a schematic representation of the diffusion of a cooling agent (12) on the outer surface of a critical module (2).

Figure 3 is a schematic representation of the diffusion of a cooling agent (12) in a critical module and on the outer surface of the critical module (2)

Figure 4 schematically illustrates the structure of the installation in an example of active operation of the distribution network.

EXPOSURE OF EMBODIMENTS

Description of the process:

The method according to the invention aims to prevent the propagation of a thermal event in an enclosure comprising a plurality of modules of electrochemical elements. The enclosure may be a room in a building or a room dedicated to the storage of bays of modules of electrochemical elements. The enclosure can also be a transport container, a transportable prefabricated shelter for the use of the modules as an emergency power source, for example for electrical / electronic equipment in the field of telecommunications. The container can also be used in systems for transporting people or goods, for example by rail. The container can have standardized dimensions according to the ISO standard.

The module (s) considered to be critical is detected because it receives heat, smoke or hot gases emitted from the location of the thermal event. These modules are considered critical because they are likely to be affected by the thermal event. A module is considered critical if one or more parameters related to its state reach or exceed a predetermined threshold. The state parameter can be chosen from the temperature of the module, the amount of smoke or the concentration of gas present around the module.

The detection of the critical state of a module is carried out using one or more detection means chosen from temperature sensors, smoke sensors and gas sensors. In the case of temperature sensors, one or more temperature sensors can be arranged on the surface of each module or in each module. One or more temperature sensors can also be placed on the surface of the elements of the module in order to detect the critical state of the module even earlier. The temperature threshold value T _s beyond which a module is considered to be in a critical state is predetermined by an operator. It can be set at 150 ° C or 200 ° C or 250 ° C or 300 ° C. One or more temperature sensors can also be placed at different locations in the enclosure, preferably as close as possible to the modules.

Critical condition detection can also be achieved using gas or smoke sensors. One or more sensors are preferably placed near the modules but can also be placed at various locations in the enclosure, such as the ceiling. One can for example choose a sensor sensitive to the presence of gas from the combustion of components of the module, for example gas from the combustion of the electrolyte of the elements of the module. The gas concentration threshold value beyond which a module is considered to be in a thermal event situation can be predetermined by an operator.

The modules adjacent to the module (s) initiating the thermal event or located near the location of the enclosure in which the thermal event occurred are generally considered to be critical. In a configuration in which the modules form a stack and are installed in a bay, several bays being placed next to each other, the critical modules will generally be:

- the module (s) located above the module (s) initiating the thermal event,

- the module (s) located below the module (s) initiating the thermal event,

- the module (s) of a bay which are at the same height as the module (s) initiating the thermal event, for example those which are located on a bay other than the one in which is located the module (s) initiating the thermal event,

- the module (s) located diagonally to the module (s) initiating the thermal event.

A cooling agent is diffused on, or in, the critical module (s), for a period and / or at a determined rate. Diffusion of the coolant can be by directed gas emission into or around the critical module (s). It can also be carried out by spraying a coolant in the liquid state. Preferably, the cooling effect is achieved by changing from a first physical state of the coolant to a second physical state. The heat flow generated by the thermal event changes the coolant, for example, from the solid state to the liquid state or from the liquid state to the gaseous state. Preferably, therefore, a cooling agent exhibiting a high latent heat of state change will be chosen. The cooling agent is preferably chosen from water, carbon dioxide and nitrogen, or any other known cooling agent, for example NOVEC® or stat-X® (https://statx.com/) .

One of the features of the process according to the invention is that it diffuses the cooling agent at a lower flow rate than in the conventional processes, over a generally longer period. This mode of diffusion makes it possible to create a cold barrier around or in the modules considered as critical. This cold barrier prevents the flow of heat or the fumes or hot gases generated by the thermal event from reaching the critical modules and causing their damage. The cold barrier also makes it possible to cool the critical modules and to maintain their temperature in a range in which they cannot in turn initiate a thermal event. The maximum value T _max of this temperature range is linked to the technology of the elements. components of the module. It can be set at 120 ° C or 100 ° C. For example, the cooling agent can be diffused for a period greater than or equal to 1 hour, preferably greater than or equal to 2 hours. It can be broadcast for a period less than or equal to 12 hours or less than or equal to 5 hours. According to one embodiment, the temperature of the critical module (s) is maintained below the maximum value of their nominal operating range set by the manufacturer.

The flow rate of the cooling agent and the duration of diffusion depend on the quantity of heat emitted by the electrochemical elements of the module initiating the thermal event or emitted by the thermal event which has occurred in a location of the enclosure not occupied by one or more modules and therefore not initiated by this or these modules. In the case of a thermal event initiated by a module, this amount of heat depends on the technology of the elements of the module and the size of the module. Typically, the coolant is water mist and the diffusion rate per critical module is between 0.1 and 2 kg / h per kWh of electrical energy stored in the critical module.

It should be noted that in the case of a thermal event initiated by one or more modules, these modules are also considered as critical modules because the value of their state parameter is always greater than the predetermined threshold Ts. Consequently, the module (s) initiating the thermal event can also receive the cooling agent, although the flow rate or the duration of diffusion of the cooling agent is insufficient to end the thermal event of which it ( s) is (or are) at the origin. The method according to the invention generally treats the module (s) initiating the thermal event and the module (s) having reached a critical state in the same way.

In a preferred embodiment, the thermal runaway initiator module (s) do not receive a cooling agent since it is often futile to attempt to extinguish a module fire by thermal runaway. The objective of the method according to the invention is therefore not to extinguish the fire in the module (s) initiating the thermal event, but rather to prevent the modules likely to be affected by the thermal event. do not in turn undergo the thermal event and propagate it.

Another feature of the method according to the invention is that one or more modules considered as non-critical, that is to say whose parameters related to their state are below a predetermined threshold, do not receive any cooling agent. . The method according to the invention therefore performs a differentiated treatment of the modules as a function of the risk. that they have to be affected by the thermal event. Generally, this risk decreases with the distance vis-à-vis either the module or modules initiating the thermal event, or the location of the enclosure not occupied by modules in which the thermal event occurred. This feature has the advantage of reducing the amount of cooling agent used compared to the amounts required in a conventional extinguishing process. Conventional extinguishing processes require the availability of a large quantity of extinguishing agent, which requires the use of large capacity storage tanks, which is expensive.

Description of the installation:

The installation specially designed for implementing the method as described above will now be described. The installation includes several modules of electrochemical elements (1, 2, 3, 4). The modules are arranged in modular racks, also called bay or “rack”. Usually the modules are stacked on top of each other and fixed to vertical uprights in the bay. Electrical connections serially connect multiple modules in the same bay to increase the voltage that a bay can deliver. An array constitutes an electrochemical storage unit. Several bays are arranged in the enclosure. They can be connected together in parallel to increase the amount of electricity available. All of the bays in the enclosure constitute an electrochemical storage system.

Each module is equipped with one or more detection means (5) of a state parameter. The detection means or means may be located on an external surface of an envelope of the module or in the interior volume defined by the envelope. The detection means can be a temperature sensor, a detector of a particular chemical compound, a flame or smoke detector or any other type of detector suitable for detecting an anomaly in the operation of a module.

The installation includes means for diffusing the cooling agent. These include a coolant reservoir (6), a coolant distribution network (7, 8), and coolant delivery devices (9) to the modules.

The cooling agent is stored in a tank (6). It is routed to the modules through the distribution network. The distribution network consists of a pipe (7) which is subdivided into different branches (8). One end of the pipeline is connected to the coolant tank. Each branch is provided at its end with a device (9) for diffusing the cooling medium. The diffusion device can be located near or in contact with a module. It can open onto the exterior surface of the module or open up inside the volume defined by the envelope of the module.

When the detection means or means of a module detect the passage of a module to a critical state, the cooling agent stored in the tank is released into the distribution network and conveyed under pressure to the diffusion device associated with the critical module.

The branches of the pipeline can operate actively. For example, one or more detection means detect the passage of a module to the critical state. They send a signal to a central coolant diffusion control device. The central control device triggers the diffusion of the coolant on, in or near the critical module (s). The central control device can for example control the opening of a valve located on the pipeline.

According to the invention, the diffusion of the cooling agent does not occur on the module or modules which are not considered as critical, it is therefore possible to use a tank with a smaller capacity than for a conventional installation in which the diffusion of the cooling agent on the modules takes place in an undifferentiated manner. In addition, the invention makes it possible to preserve the modules considered as non-critical from contact with the coolant.

When the detector (5) detects one or more critical modules (1, 2, 3), the diffusion of the cooling agent (12) on, or in, the critical module (s) (1, 2, 3) is triggered immediate or delayed. A period of time from a few minutes to a maximum of 1 hour can be set to trigger the diffusion of the coolant, in order to limit the volume of coolant used. Delayed spraying of the coolant can be beneficial in cases where the rate of heat propagation from one module to another is relatively slow.

Figure 1 illustrates an example of the installation according to the invention. It shows a side view of a module bay resting on the floor of an enclosure. The bay includes two parallel vertical uprights and four horizontal shelves attached to the two vertical uprights. Each horizontal plate serves as a support for a module (1, 2, 3, 4). The trays and the modules are four in number in Figure 1 but it is understood that their number is not limited. The cooling agent is stored in a tank (6). The distribution network consists of a pipe (7) which is subdivided into four branches (8). One end of the pipe is connected to the coolant reservoir. Each branch opens onto a side surface of a module. In the example, the module (1) initiated a thermal event (13). He is considered critical. Due to the propagation of heat from the module (1) to neighboring modules (2, 3), these are also considered critical. The module (4) is not considered to be critical because its temperature remains below the threshold value Ts due to its greater distance from the module (1) than the modules (2, 3). A coolant is injected only in the critical modules, i.e. modules 1, 2 and 3.

Figure 2 is a schematic representation of the diffusion of a cooling agent around the outer surface of a critical module (2). The ends of the branches (8) of the distribution network (7) are arranged near the modules 2 and 4. A space has been left during the installation of the modules in the bay to allow the circulation of the cooling agent to the above the module, below the module and around its side surface. The circulation of the coolant (12) creates a cold barrier around the outer surface of the critical module (2).

FIG. 3 is a schematic representation of the diffusion of a cooling agent inside a module considered to be critical (2) and then around its envelope. The ends of the branches (8) of the distribution network (7) are integrated into modules 2 and 4. The cooling medium enters the interior of the volume of the module and then leaves through one or more openings in the module. Exiting through these openings, the coolant (12) creates a cold barrier around the shell of the critical module (2).

FIG. 4 schematically illustrates a possible configuration of the installation in the case of active operation of the distribution network. A means (5) for detecting the critical state of the module (2) is arranged in contact with the internal surface of the upper wall of the casing of the module. This detection means could be located at another location in the volume defined by the envelope of the module. It could also be located outside the module or near the module or on an external surface of the wall of the module casing. In the event of detection of a critical state of the module, the detection means (5) sends a signal (15) to a centralization system (10) which controls by a signal (14) the opening of a valve (11). ) arranged on the pipe of the distribution network (7). This causes the circulation of the cooling medium (6) in the direction of the branch (8) to the critical module (2). The branch is provided at its end with a device (9) for diffusing the cooling medium. This embodiment makes it possible to keep under pressure only the reservoir of cooling agent and not the pipe of the distribution network. It is the opening of the valve which makes it possible to put the pipeline of the distribution network under pressure.

Claims

1. Method for preventing the propagation of a thermal event in an enclosure comprising several modules (1, 2, 3, 4) of electrochemical elements, said method comprising the following steps:

- detection of one or more critical modules (1, 2, 3) placed in the enclosure, affected by a thermal event (13), a module being critical when one or more parameters related to the state of the module have reached or exceed a predetermined threshold,

- diffusion of a cooling agent (12) on, or in, the critical module (s) (1, 2, 3), for a period and / or at a determined rate, one or more modules (4) which are not not detected as critical modules not receiving coolant (12).

2. Method according to claim 1, characterized in that said one or more parameters comprise the temperature inside the module (s), one or more modules being considered critical when the temperature of the module (s) exceeds a predetermined threshold value Ts.

3. Method according to one of claims 1 to 2, characterized in that said parameter (s) comprise the presence of smoke and / or gas inside the module (s), one or more modules being considered critical when the concentration smoke and / or gas exceeds a predetermined value.

4. Method according to any one of claims 1 to 3, characterized in that, in the event of a thermal event initiated by one or more modules of the enclosure, the duration and / or the flow rate are determined so that the temperature of the or critical modules (2, 3) is maintained below a threshold temperature Tmax, with the exception of the module (s) (1) initiator (s) of the thermal event.

5. Method according to any one of claims 1 to 4, characterized in that the determined duration is greater than or equal to 1 hour, preferably greater than or equal to 2 hours and, preferably, less than or equal to 12 hours.

6. Method according to any one of claims 1 to 5, characterized in that the cooling agent (12) is a compound whose cooling effect is mainly obtained by the transition from a liquid phase to a gas phase. , especially water mist or carbon dioxide or nitrogen.

7. Method according to any one of claims 1 to 6, characterized in that each module (1, 2, 3, 4) comprises an envelope having an external surface and the diffusion of the cooling agent (12) is carried out. on said outer surface.

8. Method according to any one of claims 1 to 7, characterized in that each module (1, 2, 3, 4) comprises an envelope delimiting an internal volume in which are housed electrochemical elements, and the diffusion of the cooling agent (11) is carried out by injection into said interior volume.

9. Method according to any one of claims 1 to 8, characterized in that the cooling agent is stored in liquid form in a reservoir (6).

10. Method according to any one of claims 1 to 9, characterized in that the detection of one or more critical modules (1, 2, 3) is carried out by means of one or more detectors (5) arranged in, on or near each module (1, 2, 3, 4) of the enclosure, the detector (s) (5) being a temperature threshold detector and / or a temperature sensor and / or a smoke detector or gas.

11. The method of claim 10, characterized in that when the detector (5) detects one or more critical modules (1, 2, 3), the diffusion of the cooling agent (12) on, or in, the or critical modules (1, 2, 3) is triggered immediately or delayed.

12. The method of claim 10 or 11, characterized in that when the detector (5) detects one or more critical modules (1, 2, 3), it sends a signal to a central device (10) which controls the diffusion of the cooling medium (12) on, or in, the critical module (s) (1, 2, 3).

13. Installation for implementing the method according to any one of claims 1 to 12, said installation comprising several modules (1, 2, 3, 4) of electrochemical elements, each module (1, 2, 3, 4 ) being equipped with detection means (5) capable of detecting whether the module is a critical module affected by a thermal event (1), a module being critical when one or more parameters linked to the state of the module have reached or exceeded a predetermined threshold, the installation comprising diffusion means (6 to 9), for a determined duration and / or at a determined rate, of a cooling agent (12) on, or in, the critical module (s) (1 , 2, 3) detected by the detection means (5), one or more modules (4) which are not detected as critical by the detection means not receiving cooling agent (12).

14. Installation according to claim 13, characterized in that it comprises means for controlling the diffusion rate, the cooling agent (12) being a water mist, and the means for controlling the diffusion rate being configured. so that the flow rate determined per critical module is between 0.1 and 2 kg / h per kWh of electrical energy stored in the critical module.

15. Installation according to any one of claims 13 to 14, characterized in that the diffusion means (6 to 9) comprise a reservoir (6), a distribution network (7, 8), and a plurality of distribution devices. diffusion (9) arranged on, in, or near respectively each module (1, 2, 3) of the enclosure, the cooling agent (12) being stored in the reservoir (6), the reservoir (6) being connected to the distribution devices (9) through the distribution network (7, 8).

16. Installation according to any one of claims 13 to 15, characterized in that the diffusion means (6 to 9) comprise a central device (10) for controlling the diffusion of the cooling agent (12), configured. to receive a signal (15), emitted by the detection means (5), and to trigger the broadcast coolant (12) on, in or near critical modules (2, 3) upon receipt of a thermal event detection signal (13).