FR2961705A1 - Automatic fire extinguisher for alkaline metal battery in e.g. electric bicycle, has releasing device provided with explosive load that is exploded in response to detection of departure of fire or preliminary anomaly operation of battery - Google Patents

Abstract

This automatic extinguisher for a battery containing an alkali metal comprises: - a fire enclosure (30) having an opening (34) for introducing and, alternately, removing the battery to be charged from a location (32) inside of the enclosure provided for receiving this battery, - a reservoir (56) containing a granular flame retardant material that does not ignite in contact with an alkali metal, - a pyrotechnic device (58) containing an explosive charge, the explosion of which, in response to the detection of the fire departure or the pre-existing anomaly, releases the flame retardant material on the location intended to receive the battery.

Description

AUTOMATIC EXTINGUISHER FOR BATTERY AND RECHARGE FOR THIS EXTINGUISHER

The invention relates to an automatic extinguisher for a battery containing an alkali metal. The invention also relates to a removable refill for this fire extinguisher. [002] Batteries containing alkali metals are increasingly used today and will be even more so in the future. Of these batteries, lithium or sodium batteries are the best known. [003] In particular, these batteries are or will be used for applications requiring more and more power. For example, it is envisaged to use these batteries for electric bikes, electric motorcycles or electric cars. Applications for energy storage with these batteries are also developed in other technical fields. [004] Like any electrical appliance, these batteries wear out as the charging and discharging cycles progress. In the case of batteries containing alkali metals, this wear can result in a fire starting inside the battery, for example, when charging the battery. Indeed, the inside of these batteries contains both the oxidizer and the fuel needed to maintain the fire. In addition, an alkali metal fire is very difficult or impossible to extinguish. Indeed, the alkali metals have the property of being very strongly reducing and therefore react with water or other materials conventionally used to extinguish a fire. [5] It is therefore imperative to detect and circumscribe such a fire as quickly as possible to minimize collateral damage. [6] Known automatic fire extinguishers include: - a fire enclosure having an opening for introducing and, alternately, removing the battery to be charged from a location within the enclosure provided for receiving the battery, A tank containing a flame-retardant material; a device able to automatically release the flame-retardant material on the space provided for receiving the battery in response to the detection of a fire start or a previous malfunction of the battery; likely to ignite the alkali metal. [007] Generally, these fire extinguishers are integrated with the battery chargers. For example, such an extinguisher is disclosed in the patent application JP 112 197 32. To extinguish the fire, these fire extinguishers use as a flame retardant material a gas that expels oxygen present in the enclosure of the fire extinguisher. This gas is stored in a cartridge under pressure. [ooa] In time, the pressure inside the cartridge inevitably decreases. Thus, when a battery catches fire, it is not certain that the amount of gas still contained in the cartridge is sufficient to extinguish the fire. [oos] In addition, the gas cartridge is connected to the enclosure containing the battery by long pipes. Thus, it often takes several tens of milliseconds between the moment the fire is detected and the moment when the compressed gas begins to fill the chamber. In the case of an alkali metal fire, these few tens of milliseconds of delay may be sufficient to go from a situation where the fire can be circumscribed to a situation where it is no longer possible. The invention aims to remedy at least one of these disadvantages. It therefore relates to an automatic fire extinguisher for battery containing an alkali metal, wherein - the flame retardant material is a granular material that does not ignite on contact with an alkali metal, and - the device is a pyrotechnic device containing an explosive charge whose explosion, in response to the detection of the fire departure or the pre-existing anomaly, releases the flame retardant material on the intended location to receive the battery. The granular materials do not need to be stored under pressure or compressed to be released on the location provided to receive the battery. Thus, the problem of discharging the gas cartridges is avoided. In addition, the granular materials do not impose sealing stresses on the fire enclosure as strong as in the case of gases. The explosive charge makes it possible to open the tank very quickly and accelerates the release of the flame retardant material. The shock wave generated by the explosion takes off the fireproof material optionally glued or agglomerated inside the tank. The fire extinguisher above is more robust and faster than known fire extinguishers. The embodiments of this extinguisher may include one or more of the following features: the explosive charge is placed near a wall of the tank so that the shock wave created by its explosion tears this wall to release the flame retardant material; the explosive charge is separated from the location provided for receiving the battery by at least a portion of the flame retardant material; the explosive charge is made of a material whose explosion releases a volume of inert gas at least greater than the volume of the fire enclosure; At least the tank wall facing the location intended to receive the battery is made of a material which burns or melts as soon as the temperature exceeds 500 ° C to release the flame retardant material; the fire extinguisher comprises at least one guide rail and at least one removable refill of fireproof material containing the reservoir and the pyrotechnic device, this refill being mounted in translation along the rail or rails between: an active position in which the reservoir can release the flame retardant material on the location intended to receive the battery, and - a withdrawn position in which the tank can be introduced inside the enclosure; at least one second removable refill is mounted in translation along said at least one rail behind the first refill to automatically replace the first refill after the explosion of its explosive charge. These embodiments of the fire extinguisher further have the following advantages: - use the explosive charge to tear the wall allows to quickly and efficiently release the flame retardant material; placing the explosive charge at least partly behind the flame retardant material accelerates the release of the flame retardant material because at least a portion of it is propelled towards the battery by the explosion of the explosive charge; using an explosive charge which releases an inert gas makes it possible to expel the oxygen contained in the chamber without having to use a cartridge containing a compressed inert gas for this purpose; Use of a tank whose walls are made of a material which is consumed or melts in response to an increase in temperature ensures that the flame retardant material is released even in the event of a malfunction of the pyrotechnic device; - Use removable refill guide rails to facilitate the introduction and replacement of flame retardant material of extinguisher; 30 - use several refills slidably mounted along the rails automatically adjusts the amount of fireproof material to release since as the fire is not circumscribed, these refills discharge their respective flame retardant materials one after the other on the battery . The invention also relates to a removable refill for the extinguisher above. This refill comprises: - the tank containing the flame retardant material, and - the pyrotechnic device capable of automatically releasing the flame retardant material on the location intended to receive the battery in response to the detection of a fire departure or a previous anomaly operating the battery may ignite the alkali metal. Embodiments of this refill may include one or more of the following features: the reservoir is made of a watertight material; the flame retardant material has a specific heat capacity of greater than 700 Kg, and a density strictly greater than one; the pyrotechnic device also comprises: a sensor capable of measuring a physical quantity representative of the fire start and / or of the anomaly prior to this fire departure without mechanical or electrical contact with the battery introduced into the automatic fire extinguisher, and a control unit capable of automatically triggering the explosion of the explosive charge from the measurements of the sensor, the pyrotechnic device being fixed on a wall of the reservoir or contained inside the reservoir so that the latter does not form. only one piece with the tank. These embodiments of the refill have the following additional advantages: - Use a tank made of a water-vapor-tight material makes it possible to keep dry the fireproof material and to prevent it from adhering to the walls the tank; Use of a granular flame retardant material whose heat capacity is high and whose density is greater than one makes it possible to effectively cool the fire, since this material has a high capacity for absorbing heat while keeping a small volume at tank ; - include in the recharge the pyrotechnic device allows after each fire start to easily replace not only the fireproof material but also the pyrotechnic device. The invention will be better understood on reading the description which follows, given solely by way of nonlimiting example and with reference to the drawings, in which: FIG. 1 is a diagrammatic illustration of a automatic fire extinguisher for battery; FIG. 2 is a diagrammatic sectional illustration of a refill for the extinguisher of FIG. 1; Figure 3 is a flowchart of a method of operating the extinguisher of Figure 1; and FIG. 4 is a partial schematic sectional illustration of another embodiment of the refill of FIG. 2. In these figures, the same references are used to designate the same elements. In the following description, the features and functions well known to those skilled in the art are not described in detail. Figure 1 shows an automatic extinguisher 2 for batteries containing at least one alkali metal. In FIG. 1, extinguisher 2 is shown in the particular case where it receives a battery module 4. The battery module 4 contains a battery 6 and a battery management unit 6. The battery 6 is typically a high-power battery, that is to say a battery whose power is greater than 200 Wh and preferably greater than 1 kWh. Such batteries have many applications. For example, a battery whose power is between 200 Wh and 1 kWh can be used to power an electric bike. A battery whose power is between 1 kWh and 5 kWh can be used to power a scooter or an electric motorcycle. Finally, a battery whose power is greater than 5 kWh is likely to be used to power an electric vehicle and, in particular, an electric car. These high power batteries can also be used to store energy especially for domestic applications. In order to obtain the required voltage and amperage, the battery 6 is typically formed of a plurality of electrochemical cells 10 electrically connected together in series or in parallel. By way of illustration, the battery 6 comprises four electrochemical cells 10. Each of these cells 10 accumulates, stores and, alternately, releases electrical energy. When the cells 10 accumulate electrical energy, the battery is said to be charging. When these cells 10 release electrical energy, it is said that the battery 6 discharges. Typically, each of these cells 10 comprises electrodes bathed in an electrolyte. It is the electrochemical reactions between these electrodes and the electrolyte that make it possible to accumulate, store and then release electrical energy. Generally, an alkali metal is used either to form the electrodes or to form the electrolyte. Currently, the alkali metals most used to make batteries are lithium and sodium. For example, here, the battery 6 contains lithium. It is therefore known as the "lithium battery". Unit 8 battery management 6 is known by the acronym BMS ("Battery Management System"). This unit 8 manages the charging and discharging of the battery 6. Typically, this unit 8 is able to cut off the current if a fault is detected during the operation of the battery 6. However, in no case, this unit 8 is capable of prevent the propagation of a fire that would have appeared inside the battery 6. The module 4 also comprises a connector 12 for connecting and, alternatively, disconnecting the battery 6 to an external electrical circuit. For example, here, this connector 12 is used both to recharge the battery 6 and, alternately, to power an external electrical device. In Figure 1, the connector 12 is removably mechanically connected to a corresponding connector 14. The connector 14 is itself connected via a wired connection 16 to a socket 18. The socket 18 is connected to a network 20 of electricity distribution. Typically, the network 20 is a public electricity distribution network. In this embodiment, the connector 14 and the link 16 are not part of the fire extinguisher 2 and are mechanically independent of this fire extinguisher. The battery module 4 also comprises a safety valve 22. The valve 22 makes it possible to release the gases generated by the electrochemical reactions outside the module 4 if the pressure exceeds a predetermined critical threshold. The fire extinguisher 2 comprises an enclosure 30 against fire. This enclosure 30 defines an inner location 32 for receiving the battery module 4. For this purpose, typically, the location 32 has a volume greater than 11, 51 or 101 and preferably less than 501. [0036] The enclosure 30 also comprises an opening 34 and a door 36. 34 makes it possible to introduce and, alternately, remove the module 4 from the slot 32. The door 36 is movable between an open position in which the module 4 can be introduced inside the enclosure 30 through the opening 34 and a closed position in which the door 36 closes the opening 34. In the closed position, the door 36 is able to retain inside the enclosure 30 the majority of a flame retardant material poured on the module 4. The entire walls of the enclosure 4 are sealed to the flame retardant material. For example, these walls are made of steel or polymer. The chamber 30 also includes another opening 38 to allow air to circulate inside the enclosure to cool the module 4 during the charging of the battery 6. [0041] Here, this opening 38 is also wide enough to allow the introduction into the chamber 30 of removable refill 50 flame retardant material. In this particular embodiment, the extinguisher 2 comprises a carriage 40 movable between an outer position and an inner position. The carriage 40 comprises a receptacle 42 for receiving the module 4. This receptacle 42 is for example mounted on wheels 44 for easy movement of the carriage 40 between its outer and inner positions. Here, these wheels 44 roll on a rolling track formed by a flat horizontal surface 46. The carriage 40 also includes a handle 48 allowing a user to easily move the carriage between the outer and inner positions. In the outer position, the receptacle 42 is located outside the chamber 30. In its inner position, the receptacle 42 is received in the location 32 inside the enclosure. To move from its outer position to the inner position and vice versa, the carriage 40 passes through the open 34. Here, the door 36 is secured to the carriage 40 so that when it is in its inner position , the door 36 is in its closed position while when the carriage 40 is in its outer position, the door 36 is in its open position. The fire extinguisher 2 also includes several refills 50 of fireproof material arranged one above the other. Each refill 50 is movable between an active position, shown in Figure 1, and a withdrawn position. In the active position, the recharge 50 is located above the location 32. In the withdrawn position, the latter is located outside the chamber 30. To guide each of these recharges between its active position and its removed position, extinguisher 2 comprises guide rails 52. For example, these rails 52 are vertical rods disposed on the inner periphery of the enclosure 30. In addition, to be guided by these rails 52, each refill 50 comprises eyelets 54. These eyelets 54 are traversed by the rods 52 to guide refills 50 in translation. With the stack of refills 50 on top of each other, each time a refill 50 is emptied of its flame retardant material, it is automatically replaced by the refill 50 located immediately above. Each refill 50 comprises a reservoir 56 of flame retardant material and a pyrotechnic device 58. [0049] Figure 2 shows in more detail a refill 50. The reservoir 56 has essentially two walls. An upper wall 60 and a lower wall 62 welded to each other by their peripheries. Here, these walls 60 and 62 are flexible so that the reservoir 56 forms a bag containing a flame retardant material 64. Typically, the reservoir 56 comprises between 500 g and 30 kg of flame retardant material and, preferably, between 1 and 5 kg of flame retardant material. The flame retardant material 64 is a stable oxide that does not ignite in contact with an alkali metal. In addition, the material 64 has an important ability to cool an alkali metal fire while maintaining a reduced volume. For this purpose, the flame retardant material 64 has a specific heat capacity greater than 700 J.kg.kg and preferably greater than 800 J.kg.kg and a high density, that is to say greater than 1 or 1.5 or even 2. [0052] Finally, the flame retardant material is able to flow from the tank 56 to fill the location 32. This is for example a granular material. A granular material is a material formed of grains whose largest width is less than 2 mm and, for example, less than 1 mm and, for example, between 0.01 mm and 2 mm. It can therefore be a powder. A granular material has several advantages. In particular, it has a capacity to cool a fire of alkali metal much larger than gas for the same volume. In addition, it does not impose a strong sealing stress on the enclosure 30 to retain the majority of the flame retardant material within the location 32. Here, the flame retardant material is sand or silica (SiO2 ) or magnesia (MgO). The walls of the reservoir 56 and, in particular, the inner wall 62, are made of a material suitable for: - supporting the weight of the flame retardant material 64, - tearing in response to a detonation so as to release the flame retardant material 64, and - to melt or burn for a temperature above 500 ° C or 1000 ° C. Since the material melts or is consumed at a temperature greater than 500 ° C or 1000 ° C, this ensures that the flame retardant material 64 is automatically released when the module 4 catches fire. Finally, preferably, this material is waterproof to water vapor which keeps the flame retardant material 64 dry and therefore prevent it from adhering to the walls and that it agglomerates. Typically, this material is a polymer such as low density or high density polyethylene, polyester or polypropylene. When these polymers burn, they do not produce toxic gases. The device 58 makes it possible to open the reservoir 56 in a few milliseconds, that is to say in less than 10 ms and, preferably, less than 3 ms, so that the material 64 falls by gravity onto the module 4. Here, this device 58 is integral with the reservoir 56. For example, it is heat-sealed to the bottom wall 62. The device 58 comprises one or more sensors capable of measuring each a physical quantity representative of a fire departure or a prior abnormality of operation of module 4 may trigger a fire. Preferably, these sensors are sensors without electrical and mechanical contact with the module 4. For example, the device 58 comprises a sensor 70 capable of detecting the nature of the gases that escape through the safety valve 22 of the device. module 4. Indeed, when the battery 6 heats up, the electrolyte is degraded and gases are produced. Typically, these gases may for example be carbon monoxide (CO), or hydrogen (H2), or hydrocarbon derivatives (CH4, C2H4 ...). They are evacuated via the valve 22 even before a fire.

40 An excessive amount of these gases is therefore a pre-departure anomaly. The sensor 70 measures the quantity of these gases inside the enclosure 30. The module 58 also comprises additional sensors, each of which measures a physical quantity representative of the start of the fire. Here, the module 58 comprises two of these sensors, namely a temperature sensor 72 and a smoke sensor 74. These sensors 70, 72 and 74 are housed inside a housing 76. The walls of the housing 76 are heat-sealed with the bottom wall 62. Preferably, the housing 76 has points of weakness 78 to control how it will break in response to an explosion of an explosive charge inside that case. Here, these points 78 are arranged so as to tear the wall 62. The casing 76 also comprises an explosive charge 80. By "explosive charge" is meant any material capable of exploding by creating a shock wave which can destroy the housing 76 and thus cause the wall 62 to tear. Thus, the explosive materials include the ablatable materials such as those described in the patent application EP 0 930 284. [0064] In addition, here, this explosive charge 80 generates an inert gas, that is to say which does not oxidize when it is in contact with the alkaline metal of the battery 6 under the normal operating conditions of the extinguisher 2. Preferably the inert gas generated is nitrogen or carbon dioxide. In addition, the amount of explosive charge is chosen so as to produce a volume of inert gas greater than the internal volume of the chamber 30, that is to say at least greater than 5 or 10 liters. Finally, preferably, the explosion of this explosive charge does not generate toxic gas such as nitrogen oxides or carbon monoxide. For this purpose, here, the explosive charge 80 is chosen from those listed in the tables numbers 1 and 2 of the patent application EP 0 930 284. In fact, the explosive charges listed in these tables do not release gas. toxic during their explosion. For example, these fillers do not release carbon monoxide and only very little nitrogen dioxide. For example, the weight of the load 80 is one gram. To trigger the explosion of the charge 80, the device 58 also comprises a controllable initiator 82. Here, this initiator 82 is formed of a filament 84 heated by the passage of an electric current. The initiator 82 and the various sensors are connected to a control unit 88. This unit 88 detects a start of fire or an anomaly prior to a fire starting from the measurements of the sensors 70, 72 and 74 and controls the initiator 82 so as to trigger the explosion of the load 80. [0069] Typically , the unit 88 is made from a programmable electronic calculator. Finally, the device 58 comprises a battery 90 for feeding the unit 88, the various sensors and the initiator 84 for more than a year and, preferably, for more than ten years. Optionally, this battery 90 is associated with a detector so as to be energized only when the refill 50 is introduced inside the fire extinguisher 2. [0071] The operation of the fire extinguisher 2 will now be described next of the method of Figure 3. [0072] Initially, during a step 100, the carriage 40 is in its outer position. The module 4 is then deposited inside the receptacle 42 and connected to the network 20 via the connector 12 to recharge the battery 6. In a step 102, the carriage 40 is moved from its external position towards his inner position. In a step 104, the sensors 70, 72 and 74 measure the physical quantities representative of a start of fire or an anomaly prior to the start of the fire. In a step 106, the unit 88 analyzes the measured physical quantities to detect the fire or the anomaly prior to the start of fire. During this analysis, the redundancy of the information measured by the various sensors is used to limit the probability of mistakenly triggering the explosion of the charge 80. Typically, during this analysis, the different physical quantities measured by the sensors 70, 72 and 74 are compared with predetermined thresholds. If these thresholds are crossed, then the unit 88 detects the presence of a fire departure or an anomaly prior to this fire departure. In the opposite case, the process returns to step 104. If a fire departure or an anomaly prior to this fire departure is detected, the process continues with a step 108 in which the unit 88 command initiator 82 to trigger the explosion of the load 80. For this, in this step 108, the unit 88 circulates a current in the filament 84 to trigger the explosion. In response, during a step 110, the charge 80 explodes by causing a shock wave that detonates the casing 76 essentially along the points of weakness thus causing the rapid tearing of the lower wall 62. This wave The flame-retardant material 64 is also propagated inside the material 64 and off the inner wall of the tank 56. The flame-retardant material 64 thus falls on the module 44. This material 64 absorbs the heat released and cools the start of fire. This will extinguish the fire. In addition, the explosion of the charge 80 releases an inert gas that fills the location 32 and also contributes to extinguishing the fire starting by replacing the air present inside the chamber 30. Thus, the start of fire is extinguished under the combined action of the fireproof material and the inert gas. After releasing the fireproof material 64, in a step 112, the refill 50 is automatically replaced by the refill 50 immediately above under the action of gravity. Thus, if the fireproof material released by the previous recharge 50 has not been enough to extinguish the fire, steps 104 to 112 are repeated for the next recharge. This can lead to the release of an additional amount of flame retardant material on the module 4. Thus, the fire extinguisher 2 automatically adapts the amount of flame retardant material released to the importance of the fire to be extinguished. Once the fire extinguished, during a step 114, the carriage 40 is moved from its inner position to its outer position and the receptacle 42 is emptied of fireproof material. Module 4 is also removed. The fire extinguisher 2 is again ready to receive another battery module. However, if necessary, before returning to step 100, during a step 118, one or more new refills 50 are introduced into the enclosure 30. FIG. 4 represents a refill 120 of flame retardant material suitable for to be used instead of the refill 50. This refill 120 is identical to the refill 50 except that the pyrotechnic device 58 is replaced by a pyrotechnic device 122. The device 122 is divided into two parts: - a module 124 containing the electronics necessary to detect a fire departure or an anomaly prior to this fire, and - a module 126 containing the explosive charge. For example, the module 124 contains the sensors 70, 72 and 74, the control unit 88 and the battery 90. The module 126 contains the explosive charge 80 and the initiator 82. The modules 124 and 126 are electrically connected to each other, for example, by a wire link 128. The module 124 is located on the bottom wall 62 so that the sensors 70, 72 and 74 are as close as possible to the module 4 when this recharge is in its active position. Conversely, the module 126 is located near the upper wall 60 so as to be separated, in the active position, the module 4 by the largest possible amount of fireproof material 64. For example here, two possible positions for the module 126 are shown. A solid line position in which the module 126 is located within the reservoir 56 in proximity or in direct contact with the upper wall 60. A dashed position is also shown in which the module 126 is located on the outer wall 60 outside the reservoir 56. The mode of operation of this refill 120 is identical to that of the refill 50. However, in this embodiment, the explosion of the explosive charge 80 further propels the material flame retardant 64 so that it falls faster on the module 4 than if its fall was only caused by gravity. This makes it possible to extinguish the start of fire even more quickly. Many other embodiments are possible. For example, the walls of the reservoir 56 may be rigid or semi-rigid. A combination of rigid and flexible walls is also possible. Alternatively, the fire extinguisher 2 is dimensioned so as to contain only one refill fireproof material. The fireproof material refill can be removable or not. [0092] Refills of flame retardant material can be removed after being introduced inside the enclosure 30 or not. Thus, alternatively, a non-return notch prevents the withdrawal of the refill after it has been introduced inside the chamber 30. [0093] In a variant, the extinguisher 2 has several different locations at 15. inside the enclosure 32 each adapted to receive a battery. Each location is associated with its own tanks of fireproof material or several locations are associated with the same tank to circumscribe or prevent a start of fire. For example, the tanks are dimensioned for all of these locations. Here, extinguisher 2 does not have connectors for connecting module 4 to an electricity distribution network. Alternatively, the extinguisher 2 further comprises such connectors. The pyrotechnic device 58 may also be housed entirely inside the tank 56 or on its upper wall 60. [0096] In other embodiments, the pyrotechnic device is not mechanically secured to the reservoir 56 For example, it is fixed without any degree of freedom on the enclosure 30. [0097] The various characteristics described here of the extinguisher 2 and the refill 50 can be implemented independently of the fact that the material 64 is a Granular flame retardant material and the use of an explosive charge to release this flame retardant material stored in the reservoir 56. In particular, the generation of the inert gas from an explosive charge and not from a cartridge of Compressed gas can be used in other extinguishers, for example, without granular fireproof material. 35

Claims (8)

REVENDICATIONS1. Automatic fire extinguisher for a battery containing an alkaline metal, this fire extinguisher comprising: - a fire enclosure (30) having an opening (34) for introducing and, alternately, removing the battery to be charged from a location (32) to the inside the enclosure adapted to receive this battery, - a reservoir (56) containing a flame-retardant material (64), - a device (58) capable of automatically releasing the flame retardant material on the location intended to receive the battery in response at the detection of a fire departure or a prior malfunction of the battery capable of igniting the alkali metal, characterized in that: - the flame retardant material (64) is a granular material that does not catch fire at contact with an alkali metal, and - the device (58) is a pyrotechnic device containing an explosive charge (80), the explosion of which, in response to the detection of the start of fire or the previous anomaly, releases the material fire-retardant on the intended location to receive the battery. 20 2. Fire extinguisher according to claim 1, wherein the explosive charge is placed near a wall (62) of the reservoir (56) so that the shock wave created by its explosion tears the wall to release the material. fire retardant. 25 3. Fire extinguisher according to any one of the preceding claims, wherein the explosive charge (80) is separated from the location (32) provided to receive the battery by at least a portion of the flame retardant material. 4. Fire extinguisher according to any of the preceding claims, wherein the explosive charge (80) is made of a material whose explosion releases a volume of inert gas at least greater than the volume of the fire enclosure (30). ). 5. Fire extinguisher according to any one of the preceding claims, wherein at least the wall (62) of the tank facing the location intended to receive the battery is made of a material that is consumed or melts as soon as the temperature exceeds 500 ° C to release the fireproof material. 6. Fire extinguisher according to any one of the preceding claims, wherein the fire extinguisher comprises at least one guide rail (52) and at least one removable refill (50) of flame retardant material containing the reservoir (56) and the pyrotechnic device ( 58), this refill being mounted in translation along the rail or rails between: - an active position in which the reservoir can release the flame retardant material on the location intended to receive the battery, and - a withdrawn position in which the reservoir can be introduced inside the enclosure. 7. Fire extinguisher according to claim 6, wherein at least a second removable refill (50) is mounted in translation along said at least one rail behind the first refill (50) to automatically replace the first refill after the explosion of its explosive charge. 8. Removable refill for an automatic extinguisher according to any one of the preceding claims, wherein the refill comprises: - a reservoir (56) containing a flame retardant material (64), - a device (58) capable of automatically releasing the material flame retardant on the space provided for receiving the battery in response to the detection of a fire start or a prior malfunction of the battery capable of igniting the alkali metal, characterized in that: - the flame retardant material ( 64) is a granular material which does not ignite upon contact with an alkali metal, and - the device (58) is a pyrotechnic device containing an explosive charge (80) whose explosion, in response to the detection of the departure of fire or the pre-existing anomaly, releases the flame retardant material on the intended location to receive the battery. The refill according to claim 8, wherein the reservoir (56) is made of a watertight material. 14. A refill according to any one of claims 8 to 9, wherein the flame retardant material (64) has a specific heat capacity greater than 700 J.Kg-1 K_, and a density strictly greater than one. Refill according to any one of Claims 8 to 10, in which the pyrotechnic device also comprises: a sensor (70, 72, 74) capable of measuring a physical quantity representative of the fire start and / or of the anomaly prior to this fire departure without mechanical or electrical contact with the battery introduced into the automatic extinguisher, and - a control unit (88) capable of automatically triggering the explosion of the explosive charge from the measurements of the sensor, the pyrotechnic device being fixed on a wall of the tank (56) or contained inside the tank (56) so that it forms a single piece with the tank.