FR3137585A1 - Autonomous self-supporting fire protection structure - Google Patents

Abstract

Title: Autonomous self-supporting fire protection structure The invention relates to a transportable fire-fighting structure to be installed on a floor (10) of an area, intended to protect said area against fires, comprising: - a self-supporting frame (2 ) mechanically supporting the structure (1), - a reserve container for extinguishing liquid (3) configured to store a fire extinguishing liquid, - a multidirectional sprinkler (4), - a booster (5) fluidly connected to the liquid reserve container (3) and to the multidirectional sprinkler (4), comprising means of connection with external piping, and configured to supply a flow of fire extinguishing liquid to the multidirectional sprinkler (5 ) or to said external piping, - an electronic detection and control unit (7) configured to detect a position of an outbreak of fire or a fire in the zone, configured to generate an orientation command of the multidirectional sprinkler (4) as a function of said fire starting position. Figure for abstract: [Fig. 1]

Description

Autonomous self-supporting fire protection structure

The present invention belongs to the technical field of preventing fire outbreaks and protecting sensitive areas against fires of all kinds, in particular inside or in the exterior vicinity of buildings, on construction sites, or even nearby of an area containing flammable vegetation.

The invention relates more particularly to an improved fire protection structure, intended to be installed on the ground in an area presenting a fire risk.

State of the art

The most common solution for fire protection of sensitive areas, and in particular the interior of buildings accommodating people, consists of distributing fire extinguishers within the building. However, using a fire extinguisher can be difficult and requires human intervention. Standard fire extinguisher devices do not include automatic detection of fire outbreaks. Finally, fire extinguishers are generally not easily transportable.

Mobile fire-fighting devices exist, for example a device equipped with casters described in the French patent application publication bearing the number FR 2 498 458 A1. This wheeled device also includes personal protective equipment such as gloves, glasses and a smoke mask. However, the device described in this document still requires triggering by a person.

To overcome this major drawback, fire protection devices incorporating an automated triggering function were subsequently proposed. These devices typically include a sprinkler powered for example by a pump, the sprinkler being started by an automated fire outbreak detector comprising a sensor. The sensor is for example a smoke detector or a temperature sensor. Such devices prepare and complete the subsequent intervention of the firefighters, since they make it possible to initiate the extinction of the fire and contain its spread, before the firefighters can intervene in the area and complete the extinction of the fire. 'fire.

However, known autonomous fire protection devices are generally very bulky, not very compact and not transportable.

In addition, the deployment of these known devices is often difficult, especially since a connection to an external water reserve and/or to the urban water distribution network is generally necessary for the proper functioning of the pump and the sprinkler.

As a result, many isolated areas, particularly in the mountains, cannot currently be protected satisfactorily by existing autonomous fire-fighting devices. For the safety of people and the integrity of these zones, it is necessary to find fire protection devices more adapted to the constraints of these zones.

Finally, existing fire protection devices must generally be associated with external mechanical reinforcement elements for their support, which generates additional difficulties for the implementation of these devices.

In general, the ease of deployment and use, autonomy, modularity and effectiveness of fire protection devices of the current state of the art can therefore be improved.

General description of the invention

In view of the above, known autonomous fire-fighting devices, aimed at automatically extinguishing emerging fires, or at least at limiting the spread of fires already declared before an intervention by the firefighters, must subject to improvements to meet public safety issues.

In particular, there is a need for a fire protection device which is fully self-sufficient, which does not require external mechanical support, and which is able to operate if necessary without connection to a public water distribution network or to an external tank.

We are also looking for, preferably, an autonomous fire protection device which can cover a fairly large perimeter, and which is particularly suitable for automatically extinguishing or containing an outbreak of fire in all directions.

In addition, existing devices can be improved in terms of reducing floor space, in order to sufficiently protect cramped and isolated areas, or even very dense areas in which saving space is crucial.

To meet these needs, the present invention relates according to a first aspect to a transportable fire-fighting structure configured to be installed on the ground of an area, intended to protect said area against fires, the structure comprising:
a self-supporting frame mechanically supporting the structure,
a fire extinguishing liquid reserve container configured to store a fire extinguishing liquid,
a multidirectional sprinkler carried by the self-supporting frame,
a booster fluidly connected to the liquid reserve container and fluidly connected to the multidirectional sprinkler, the booster further comprising connection means configured to authorize connection of the booster with external piping,
the booster being configured to supply a flow of fire extinguishing liquid at an extinguishing pressure to the multidirectional sprinkler or to said external piping,
an electronic detection and control unit, configured to detect a position of an outbreak of fire or a fire in the zone, the multidirectional sprinkler being configured so that its orientation is adjustable as a function of said starting position fire or conflagration.

The fire-fighting structure according to the invention operates autonomously, allowing automatic detection and immediate limitation of fire outbreaks. No human presence is necessary to detect and contain fire outbreaks.

Such autonomy of the device is particularly useful in the case where the areas to be protected are isolated and difficult to access by firefighters and emergency services, which may be the case in areas located in medium or high mountains. The autonomous fire-fighting structure of the invention ensures that these isolated areas are protected reactively and effectively.

An important additional advantage of the fire-fighting structure according to the invention is its very moderate size, particularly in terms of surface area occupied on the ground. Indeed, all the modules are preferably integrated within a single self-supporting frame, which can preferably be of a general parallelepiped shape. The extinguishing liquid reserve is independent and contained within the structure. In particular, in the case where fire protection must be deployed inside or near a building, a considerable saving of space can be achieved by the protective structure of the invention.

An additional advantage is that the autonomous structure according to the invention is transportable and can therefore be easily moved according to needs, removed and/or replaced, or even redeployed from one site to another. In particular, the autonomous structure according to the invention can be transported to a workshop, in order to ensure maintenance and/or upkeep of the structure.

The fire protection structure of the invention is also intended to be self-sufficient, because it can operate if necessary without any connection to the public water distribution network, and allows you to do without a lot of electricity and costs. an HVAC lot (this acronym is commonly used to designate the “Heating, Ventilation and Air Conditioning” function in the field of building ventilation equipment).

Optional and non-limiting characteristics of the fire protection structure of the present invention may be the following, considered alone or according to any technically possible combination of these characteristics:

- the self-supporting frame comprises a lower surface configured to rest on the ground, and comprises an upper surface extending parallel to the lower surface.

- the frame comprises at least one post supporting the upper surface and resting on the lower surface, the liquid reserve container extending inside an internal volume delimited by said post, lower surface and upper surface.

- the liquid reserve container occupies a volume greater than or equal to 30% of said internal volume provided by the self-supporting frame, preferably greater than or equal to 50% of said internal volume.

- the self-supporting frame has a general parallelepiped shape.

- the self-supporting frame has an external length of between 2.0 meters and 8.0 meters.

- the self-supporting frame has an exterior width of between 1.0 meters and 4.0 meters.

- the self-supporting frame has an external height of between 1.0 meters and 4.0 meters.

- the self-supporting frame is made of a metallic material, preferably steel.

- the self-supporting frame is made of a material with a fire resistance of classification M0 or M1 or M2, said classifications being established in accordance with French standard NF P92-507.

- the electronic detection and control unit comprises at least one sensor among the following: a temperature variation sensor, and/or a smoke detector, and/or an infrared radiation sensor, and/or a radiation sensor ultraviolet, and/or an optical camera.

- the electronic detection and control unit comprises a communication interface configured to issue the electronic command for orientation of the multidirectional sprinkler remotely over a telecommunications network, preferably by Internet and/or Ethernet and/or 3G and /or 4G and/or 5G and/or voice GSM.

- the electronic detection and control unit comprises a communication interface configured to emit an alarm signal to a remote operator, preferably via Internet and/or Ethernet and/or 3G and/or 4G and/or 5G and/or voice GSM.

- the booster comprises at least one pump and at least one motor, said motor being thermal or electric and being configured to operate said pump.

- the booster includes two pumps mounted in parallel.

- the booster is configured to provide, in operation, a flow of extinguishing liquid at a pressure between 1 bar and 12 bars.

- the fire-fighting structure comprises an autonomous power unit comprising an electric battery and/or comprising a fuel reserve, the engine being supplied with energy by said autonomous power unit.

- the fire-fighting structure further comprises an electronic management module configured to generate a booster control, as a function of at least one parameter detected by the electronic detection and control unit.

- the electronic detection and control unit is configured to transmit at regular intervals a periodic signal encoding at least one piece of data representative of a working state of the structure, preferably by Internet and/or Ethernet and/or 3G and/ or 4G and/or 5G and/or voice GSM.

- the fire-fighting structure further comprises rainwater collection means connected to the liquid reserve container.

According to a second aspect, the present invention relates to a fire protection system, configured to protect an area against fires autonomously, the system comprising a transportable fire-fighting structure as defined above, and further comprising a volume of fire extinguishing liquid stored in the liquid reserve container integrated into said fire-fighting structure. The volume of fire extinguishing liquid preferably comprises water mixed with an adjuvant liquid and/or water mixed with a retardant liquid.

General description of the figures

Other aims and advantages of the invention will emerge on reading the detailed description below, presented by way of illustration and not limitation, said detailed description being supplemented by the figures below among which:

There is a general schematic representation, in perspective, of a fire protection structure according to an exemplary embodiment of the invention. The fire protection structure is here positioned on the ground in an area to be protected.

There is an alternative view from the rear of the structure according to the .

There functionally represents an example of a booster circuit, which can be integrated into the fire protection structure according to Figures 1 and 2.

Detailed description of an example of embodiment of the invention

Figures 1 and 2 schematically illustrate an autonomous fire protection structure 1 according to an exemplary embodiment of the invention.

The protective structure 1 is configured to be positioned on a surface of an area to be protected, typically on a substantially flat ground 10 of the area. Protective structure 1 is typically deployed and maintained by professionals in the field of construction and building, and/or by local authorities, although use by individuals is also envisaged.

The area to be protected is for example located inside or near a building, on a construction site, on a site including flammable vegetation, etc.

The area to be protected is typically small, of the order of a few meters long and/or wide. Indeed, and as will be seen below, the dimensions and the autonomous and self-supporting nature of the protective structure 1 make it possible to envisage an installation of this structure on a reduced floor space.

The protective structure 1 is advantageously self-supporting, that is to say that this structure 1 mechanically supports itself, in particular via its frame 2, without an external reinforcing or scaffolding element being necessary for the stability of the structure on the surface. Thus, in the present example, no external mechanical reinforcement element (such as a base, a beam, etc.) cooperates with the reinforcement 2 of the structure 1.

The protective structure 1 further comprises here a container 3 for reserve extinguishing liquid, a sprinkler 4 preferably multidirectional, a booster 5, a management module 6, an electronic unit 7 for detection and control, and a unit 8 autonomous power supply. These different elements are described in detail below.

Self-supporting frame to support the fire-fighting structure

The self-supporting frame 2 providing mechanical support for the structure 1 is made of a material of high mechanical strength and rigidity, allowing the support and maintenance of the structure 1. Preferably, the frame 2 is made of a metallic material . In this example, reinforcement 2 is made of steel.

Importantly, the frame 2 is made of a material with very high fire resistance. In fact, frame 2 must, to a certain extent, resist fire outbreaks.

To this end, preferably, the frame 2 is manufactured from a material having a fire resistance of classification M0 or M1 or M2, said classifications being established in accordance with the French standard NF P92-507 administered by AFNOR entitled “ Security fire - Building - Construction materials - Fire exits ”. The French standard NF P92-507 defines a standardized classification of construction and furnishing materials based on their reaction to fire. Here, the fire resistance of the materials of reinforcement 2 is preferably level M2.

Preferably, the frame 2 is designed so that all the functional modules of the fire-fighting device are integrated inside said frame 2. In particular, the reserve 3 of extinguishing liquid is contained in said frame 2.

Thus, a considerable saving of space can be achieved, which is particularly useful in the case where fire protection must be deployed inside or in the vicinity of a building in which the deployment surface may be small. In addition, the fire-fighting structure 1 is transportable and self-supporting. Said structure can therefore be moved, removed and/or replaced as needed.

To this end, the self-supporting armature 2 here has a general hollow parallelepiped shape, and defines a hollow internal volume in which the different modules can be placed.

Here, the frame 2 comprises a lower surface 20 configured to rest on the ground, an upper surface 21 extending parallel to the lower surface 20, and at least one post 22 supporting the upper surface 21 and resting on the lower surface 20 Preferably, the frame 2 comprises four posts 22 parallel to each other, at the corners of the upper and lower surfaces. The liquid reserve container 3 extends inside the volume delimited by said posts and the upper and lower surfaces.

As indicated above, the fire-fighting structure 1 is designed to obtain a reduced footprint and occupy limited floor space. The structure can thus equip cramped isolated areas, including in the mountains, inside or near a building, etc.

The exterior volume occupied by structure 1 is thus small, preferably less than 40 cubic meters, and the floor area occupied by structure 1 is reduced, preferably less than 20 square meters.

Preferably, structure 1 has the following external dimensions:
- an exterior length “L” of between 2.0 meters and 8.0 meters (6.1 meters in this example);
- an exterior width “l” of between 1.0 meters and 4.0 meters (2.4 meters in this example);
- finally, an exterior height “H” of between 1.0 meters and 4.0 meters (2.6 meters in this example).

The lower surface 20 of the frame is here partly occupied by the liquid reserve 3. The rest of the lower surface 20 forms a floor of the cabin on which one or more individuals can circulate.

The upper surface 21 can optionally accommodate several functional elements of the fire-fighting structure 1. In particular, as will be seen below, the multidirectional sprinkler 4 can be mounted on the upper surface 21.

In addition, an autonomous energy supply unit 8 can equip the structure 1. The power supply unit 8 comprises for example one or more electric batteries and/or a fuel reserve. The energy supply of the modules of structure 1 is electrical and/or thermal. As will be seen below, the motorization necessary for the operation of the modules of structure 1 can be directly supplied with energy by such an independent power supply unit 8. An advantage is to be able, if necessary, to avoid the need for a connection to the public electricity distribution network.

Here, the fire-fighting structure 1 is equipped with substantially flat photovoltaic cells, placed above the upper surface 21. Alternatively or in combination, a wind system and/or a fuel reserve can equip the structure 1.

Fire extinguishing fluid reserve

As illustrated in Figures 1 and 2, the liquid reserve 3 is preferably of a generally parallelepiped shape, even if other geometries can be considered. Reserve 3 comprises for example water, optionally and advantageously mixed with a retarding liquid and/or an adjuvant liquid. The contents of reserve 3 thus constitute a fire extinguishing liquid that can be dispersed at the outlet of the sprinkler 4 and/or at the outlet of external piping.

In the present example, a rear wall wall 12 extends vertically from the lower surface 20 to the upper surface 21. The liquid reserve 3 is preferably placed against the rear wall wall 12. The reserve 3 preferably occupies a volume greater than or equal to 30% and less than or equal to 70% of the internal volume provided by the reinforcement 2, preferably greater than or equal to 50% and less than or equal to 70% of said internal volume.

The internal space of the frame 2 not occupied by the reserve 3 forms a cabin, in which a person can stand. A door 13 is optionally made in the rear wall 12, allowing access to the cabin by one person.

In the present example, the sides of the frame 2 different from the rear side remain open, and do not have a closing wall.

A useful volume of the reserve 3 is for example greater than or equal to 10 cubic meters and less than or equal to 30 cubic meters. The useful volume of the tank here is equal to approximately 18 cubic meters. A large volume of fire extinguishing liquid, sufficient to at least temporarily contain an outbreak of fire, can therefore be stored there, while ensuring a moderate footprint.

Thanks to the reserve 3 of extinguishing liquid, the fire-fighting structure 1 can operate autonomously if necessary, without connection to any public water distribution network or to any external source of liquid. The liquid reserve 3 supplies the multidirectional sprinkler 4 and the booster 5 with a flow of fire extinguishing liquid, in the event of a fire detected in the vicinity of the structure. The fire-fighting structure 1 according to the invention is thus intended to be self-sufficient.

It is also advantageous to provide rainwater recovery to supply the reserve 3. To this end, in the present example, the upper surface 21 of the frame 2 comprises collection means 11, fluidly connected to reserve 3.

Booster; Multidirectional sprinkler

The autonomous fire extinguishing means on board the fire-fighting structure 1 are here mainly constituted by a sprinkler 4, capable of projecting a flow of extinguishing liquid in all directions. To do this, the sprinkler 4 is preferably mobile in rotation 360° relative to the frame 2, around a substantially vertical axis.

The multidirectional sprinkler 4 is, in this example, mounted on an exterior side of the self-supporting frame 2. The sprinkler 4 is preferably located on the upper surface 21 of the frame 2, here along an edge of the upper surface 21.

The sprinkler 4 can be controlled electronically. Here, the sprinkler 4 is in particular configured to receive an angular orientation command transmitted by a communication interface, said sprinkler orientation command being generated preferentially by the electronic control detection unit 7 or by a separate module communicating with said detection unit 7.

A booster 5 is embedded in the fire-fighting structure 1. The booster 5 is configured to be triggered automatically in the event of detection of a fire outbreak by the detection unit. Drawing then from the reserve 3, the booster 5 can produce, from the extinguishing liquid stored in this reserve, a flow rate and an extinguishing pressure suitable for supplying the sprinkler 4. The booster 5 is fluidly connected with a part to the reserve 3, and on the other hand to the multidirectional sprinkler 4.

Advantageously, the booster 5 can further comprise connection means 59 configured to allow connection of the booster 5 to external piping. Thus, if necessary, the flow of extinguishing liquid supplied by the multidirectional sprinkler 4 can be supplemented, or replaced, by a flow of extinguishing liquid leaving the external piping.

The booster 5 is preferably configured to supply, in operation, a flow of extinguishing liquid at an extinguishing pressure of between 1 bar and 12 bars, for example to the sprinkler 4 and/or to the aforementioned external piping.

In the present example, the booster 5 is directly positioned next to a wall of the container forming the reserve 3, on the cabin side.

We have functionally represented on the appended a circuit of the booster 5, according to a non-limiting example of embodiment.

The booster 5 comprises at least one pump 52 capable of supplying a flow of liquid at a flow rate and an extinguishing pressure sufficient to power the sprinkler 4. The fire-fighting structure 1 comprises a thermal or electric motor configured to operate said pump .

The booster 5 also preferably integrates a control cabinet. As will be detailed below, the booster 5 can receive a command from an electronic management module, depending on the signals transmitted by the fire detection unit.

The booster 5 according to the present example is preferably supplied with three-phase current with a voltage of 400 volts.

In the present example, the booster 5 comprises two pumps 52 mounted in parallel, capable of setting in motion a flow of extinguishing liquid between an inlet 530 (suction collector) and an outlet 531 (discharge pipe).

Preferably, the pumps 52 are associated with non-return valves and isolation valves in order to ensure control of the extinguishing flow. Here, each pump 52 is associated with a non-return valve 54, and is associated with a pair of isolation valves 55 making it possible to selectively isolate each pump 52.

The booster 5 is preferably also equipped with a series of sensors, making it possible to check the correct operation of the booster 5 and to monitor the operating state of the structure. In the present example, the booster 5 comprises a first pressure sensor 56 (preferably a 0-16 bar pressure gauge) at the suction inlet, and/or a second pressure sensor 56 (preferably a 0 pressure gauge -16 bar) at the discharge outlet. The booster 5 here also includes a pressure switch 58.

In addition, the booster 5 is optionally equipped with a water shortage sensor 57.

Electronic fire detection unit; Electronic management module

Advantageously, the fire-fighting structure 1 operates autonomously with automatic detection of fire outbreaks within the protection perimeter of the structure. No human presence is necessary for fire detection.

Detection and monitoring of the protective perimeter of the structure are ensured by an electronic detection and control unit 7, comprising one or more sensors preferably placed outside the module. These sensors are capable of scanning a predetermined perimeter around the fire-fighting structure 1.

Preferably, the electronic unit 7 comprises at least one sensor and preferably several sensors chosen from the following group: a temperature variation sensor, and/or an infrared radiation sensor, and/or a smoke detector, and/or or an ultraviolet radiation sensor, and/or an optical camera.

Thus, the electronic unit 7 is able to autonomously and reactively detect an outbreak of fire within the perimeter by reacting to an increase in surface temperature and/or to the appearance of infrared radiation and/or to the appearance of ultraviolet radiation. Such detection prepares the subsequent intervention of the firefighters, since it makes it possible to initiate the extinction of the fire and contain its spread. Here again, the fire-fighting structure 1 is intended to be self-sufficient.

In the present example, the electronic unit 7 comprises a surface temperature sensor (not illustrated in the attached figures) and/or a camera 70. The camera 70 here comprises an optical camera placed on the upper surface 21 of the armature 2 self-supporting. Alternatively or in combination, the camera 70 can allow detection of infrared radiation and/or detection of ultraviolet radiation in the protection perimeter.

Preferably and advantageously, the electronic detection unit 7 is also configured to receive an orientation command from the multidirectional sprinkler 4 as a function of at least one parameter detected by the electronic detection unit 7.

Here, the orientation of the multidirectional sprinkler 4 is automatically adjusted according to the detected position of the start of fire or fire. The detected position is for example recorded in an electronic memory of the structure, for example in the form of ground coordinates.

An angular movement command of the sprinkler 4 is then processed by calculation means of the electronic unit 7 as a function of said detected position, so as to move for example the aiming axis of the sprinkler 4 so that that -this disperses the extinguishing liquid at the start of the fire.

Preferably and advantageously, the electronic unit 7 is associated with an electronic management module 6 ensuring the control of the booster 5.

The booster 5 receives an electronic command from the electronic management module 6 as a function of the measurements transmitted by the electronic unit 7. The control of the booster 5 includes for example an extinguishing flow setpoint and/or a pressure setpoint extinction to be supplied at the inlet of the multidirectional sprinkler 4, and/or at the inlet of an external pipe connected to the booster 5 via the connection means 59. The control of the booster 5 is for example determined by means of calculating the electronic management module 6.

The electronic management module 6 is for example integrated into a control cabinet of the booster 5.

Preferably, the structure 1 comprises a telecommunications interface, configured to issue an electronic command for orientation of the sprinkler 4 remotely over a telecommunications network, preferably by Internet and/or Ethernet and/or 3G and/or 4G and/or 5G and/or voice GSM. The electronic orientation command of the sprinkler can then be received and processed by the electronic unit 7. Alternatively, the orientation command of the sprinkler can be generated directly at the level of the electronic unit 7 or transmitted in wired to the electronic unit 7.

In addition, a periodic signal encoding at least one piece of data representative of a working state of the structure can be generated and transmitted periodically over a remote network, preferably by Internet and/or Ethernet and/or 3G and/or 4G. and/or 5G and/or voice GSM. The periodic signal can pass through the telecommunications interface.

Alternatively or in combination, an alarm signal representative of the location and/or intensity of an outbreak of fire within the protection perimeter of the structure can be generated and transmitted periodically over a remote network, by example through the telecommunications interface.

Such a telecommunications interface is for example integrated into the electronic management module 6.

Thus, in the event of detection of a fire outbreak and in the event of triggering of the booster, the fire-fighting structure automatically alerts a remote electronic unit, belonging for example to fire protection services: firefighters and/or civil security and/or or local authorities, etc.

The alarm transmitted to the fire protection services can specify the location and/or intensity of a fire outbreak and/or specify the type of fire outbreak. Such an alarm prepares and completes the subsequent intervention of the firefighters to extinguish the fire detected in the area.

The autonomous fire-fighting structure of the invention thus ensures that isolated areas difficult to access by firefighters are protected in a responsive and effective manner.

Claims (15)

Transportable fire-fighting structure configured to be installed on a floor (10) of an area, intended to protect said area against fires, the structure (1) comprising:
- a self-supporting frame (2) mechanically supporting the structure (1),
- a extinguishing liquid reserve container (3) configured to store a fire extinguishing liquid,
- a multidirectional sprinkler (4) carried by the self-supporting frame (2),
- a booster (5) fluidly connected to the liquid reserve container (3) and fluidly connected to the multidirectional sprinkler (4), the booster (5) further comprising connection means (59) configured to authorize connection of the booster (5) with external piping,
the booster (5) being configured to supply a flow of fire extinguishing liquid at an extinguishing pressure to the multidirectional sprinkler (4) or to said external piping,
- an electronic detection and control unit (7), configured to detect a fire starting position or fire at the zone level, the multidirectional sprinkler (4) being configured so that its orientation is adjustable according to said fire starting position or fire. Fire-fighting structure according to claim 1, wherein the self-supporting frame (2) comprises a lower surface (20) configured to rest on the ground, comprises an upper surface (21) extending parallel to the lower surface (20) , and comprises at least one post (22) supporting the upper surface (21) and resting on the lower surface (20),
the liquid reserve container (3) extending inside an internal volume delimited by said post (22), lower surface (20) and upper surface (21). Fire-fighting structure according to claim 2, in which the liquid reserve container (3) occupies a volume greater than or equal to 30% of said internal volume provided by the self-supporting frame (2), preferably greater than or equal to 50% of said internal volume. Fire-fighting structure according to any one of claims 1 to 3, in which the self-supporting frame (2) has a general parallelepiped shape and has the following external dimensions:
- an exterior length (L) of between 2.0 meters and 8.0 meters; And
- an exterior width (l) of between 1.0 meters and 4.0 meters; And
- an exterior height (H) of between 1.0 meters and 4.0 meters. Fire-fighting structure according to any one of claims 1 to 4, in which the self-supporting frame (2) is made of a metallic material, preferably steel. Fire-fighting structure according to any one of claims 1 to 5, in which the self-supporting frame (2) is manufactured from a material having a fire resistance of classification M0 or M1 or M2, said classifications being established in accordance with the standard French NF P92-507. Fire-fighting structure according to any one of claims 1 to 6, in which the electronic detection and control unit (7) comprises at least one sensor among the following: a temperature variation sensor, and/or a detector smoke, and/or an infrared radiation sensor, and/or an ultraviolet radiation sensor, and/or an optical camera (70). Fire-fighting structure according to any one of claims 1 to 7, in which the electronic detection and control unit (7) comprises a communication interface configured to issue the electronic command for orientation of the multidirectional sprinkler (4 ) remotely on a telecommunications network, preferably via Internet and/or Ethernet and/or 3G and/or 4G and/or 5G and/or voice GSM,
and/or being configured to emit an alarm signal to a remote operator, preferably via Internet and/or Ethernet and/or 3G and/or 4G and/or 5G and/or voice GSM. Fire-fighting structure according to any one of claims 1 to 8, in which the booster (5) comprises at least one pump and at least one motor, said motor being thermal or electric and being configured to actuate said pump, the booster ( 5) preferably comprising two pumps (52) mounted in parallel. Fire-fighting structure according to any one of claims 1 to 9, in which the booster (5) is configured to provide, in operation, a flow of extinguishing liquid at a pressure of between 1 bar and 12 bars. Fire-fighting structure according to any one of claims 1 to 10, the fire-fighting structure comprising an independent power supply unit (8) comprising an electric battery and/or comprising a fuel reserve. Fire-fighting structure according to any one of claims 1 to 11, the fire-fighting structure further comprising an electronic management module (6) configured to generate a booster control, as a function of at least one parameter detected by the electronic detection and control unit (7). Fire-fighting structure according to claim 12, in which the electronic detection and control unit (7) is configured to transmit at regular intervals a periodic signal encoding at least one piece of data representative of a working state of the structure, of preferably by Internet and/or Ethernet and/or 3G and/or 4G and/or 5G and/or voice GSM. Fire-fighting structure according to any one of claims 1 to 13, in which the fire-fighting structure further comprises rainwater collection means (11) connected to the liquid reserve container (3). Fire protection system, configured to protect an area against fire autonomously, said system comprising:
- a transportable fire-fighting structure (1) according to any one of claims 1 to 14;
- a volume of fire extinguishing liquid, stored in the liquid reserve container (3) integrated into said fire-fighting structure (1), the fire extinguishing liquid volume preferably comprising water mixed with an adjuvant liquid and/or water mixed with a retardant liquid.