ITVR20120214A1 - DEVICE FOR THE EMISSION OF A JET OF FLUID - Google Patents

Description

DESCRIPTION

â € œDevice for the emission of a jet of fluidâ €

The present invention relates to a device for the emission of a jet of fluid. In particular, the present invention relates to a device for extinguishing fires through a jet of fluid comprising an extinguishing liquid.

However, the device according to the present invention can also be used for the abatement of harmful substances, for the abatement of dust, for the cooling of a specific area or volume of air, for the mitigation of the effect resulting from an explosion or for other uses not expressly indicated here etc. ...

Preferably, the present invention is suitable for putting out medium and large fires. Even more particularly, the present invention can be used to extinguish fires in places that are difficult to reach, such as for example tunnels and galleries.

Currently, the known technique for extinguishing fires provides for the use of a device for the emission of a jet of fluid connected to a fuel system through a flexible duct. Preferably, this feeding system is fixed and comprises one or more emission members of the extinguishing liquid. This power supply system and these extinguishing liquid emission devices are generally installed near the fire place. The device for the emission of a jet of fluid normally includes a lance suitably connected to the fuel system by means of a flexible tubular duct.

It should be noted that the extinguishing liquid usually includes water mixed with foam.

Normally, the lance is fixed to a support structure or, more frequently, it is held in the hand by an operator and turned towards the fire to be extinguished. It should be noted that in this known technology the extinguishing of the fire occurs mainly by suffocation of the flames. In fact, it is the foam contained in the jet of the extinguishing liquid which, by covering the flames, extinguishes the fire.

Disadvantageously, in case of fires in predetermined places in which a risky situation arises, it is not always possible to have an extinguishing liquid emission organ near the fire place. For example, in the event of a fire in a road tunnel or in a particular place in an industry. Therefore, after having connected the lance to an extinguishing liquid emission device, it is often necessary to take the lance to the fire site by exploiting the length of the flexible duct.

In other words, the flexible conduit is dragged across the floor or ground. Furthermore, since the fire can occupy a large area, it is often necessary to move the lance during the emission of the liquid in order to direct the jet of extinguishing liquid in the most appropriate direction. This operation also implies that the flexible duct is dragged on the floor or on the ground.

Since in these conditions the flexible duct is full of water, there is a risk of tearing the duct as a result of this dragging, with consequent interruption of the supply of liquid and an unacceptable delay in extinguishing the fires. In addition to this, to put out fires in narrow tunnels it is necessary to use a known device of reduced size, such as for example a simple hose carried by hand by an operator. Disadvantageously, since the direct intervention of an operator is required, it is not possible to approach the fire beyond a certain limit without endangering its safety.

In this situation, the purpose of the present invention is to provide a device for the emission of a jet of fluid which remedies the aforementioned drawbacks. In particular, the object of the present invention is to provide a device for the emission of a jet of fluid having greater reliability, in particular in tunnels or passages.

Even more particularly, it is an object of the present invention to provide a device for the emission of a jet of fluid which is capable of lowering the degree of wear of the connection duct.

Furthermore, it is an object of the present invention to provide a device for the emission of a jet of fluid which can be easily maneuvered in places where there is no liquid emission organ in the close vicinity.

The indicated purposes are substantially achieved by a device for the emission of a jet of fluid according to what is described in the attached claims.

Further characteristics and advantages of the present invention will become clearer from the detailed description of a preferred, but not exclusive, embodiment of a device for the emission of a fluid jet illustrated in the accompanying drawings, in which:

Figures 1 and 2 show a schematic side view of two respective embodiments of the device for the emission of a jet of fluid according to the present invention;

- figure 3a shows, in an axonometric view, a detail of the device for the emission of a jet of fluid of figures 1 and 2;

- figure 3b shows, in side view, a detail of the device for the emission of a jet of fluid of figures 1 and 2 with some parts removed to better highlight others;

- figure 3c shows, in front view, a detail of the device for the emission of a jet of fluid of figures 1 and 2.

With reference to the aforementioned figures, the reference number 1 globally indicates a device for the emission of a jet of fluid according to the present invention.

Hereinafter, reference will be made almost exclusively to the use of the device 1 in the fire-fighting sector only by way of example without limiting the present invention to such use as previously disclosed. In particular, the device 1 for the emission of a fluid jet comprises a cannon 32 configured to deliver a nebulized fire-fighting fluid through an outlet 4 (Figures 3a, 3b, 3c).

In detail, the gun 32 comprises a tubular body 2 extending between an inlet 3 and the aforementioned outlet 4. Inside the tubular body 2 a passage zone â € œZâ € is defined. Preferably, this tubular body 2 is a cylindrical body with a circular section.

Furthermore, as shown in Figure 3a, the inlet 3 and the outlet 4 are defined by respective opposite circular edges of the tubular body 2. In addition, the gun 32 comprises blowing means 5 operatively associated with the tubular body 2 to generate an air flow along a propagation direction P of the air that goes from the inlet 3 to the outlet 4. In other words, the air flow generated by the blowing means 5 propagates in the area of passage Z along the direction of propagation P. Preferably, this direction of propagation P is straight. Furthermore, in the preferred embodiment illustrated in the attached figures, the blowing means 5 are mounted in correspondence with the inlet 3 of the tubular body 2 and suck the air from the outside to blow it towards the inside of the tubular body 2 .

As it is possible to see in figure 3b, the blowing means 5 include a fan 6 with linear ejection geometry that sucks the air from the external environment and blows it inside the tubular body 2 towards the mouth outlet 4. In detail, the fan 6 comprises a plurality of blades 7 distributed in a substantially radial manner with respect to the direction of propagation P.

In addition, the fan 6 is mechanically connected to a motor 8 which makes it rotate. Preferably, the fan 6 is positioned inside the tubular body 2.

In the preferred embodiment, the motor 8 is mounted externally to the tubular body 2 and in proximity to the inlet 3. In figure 2 it is possible to see that the motor 8 is mounted on a frame 9 (which will be better explained later ) of the device 1 and is connected to the fan 6 by means of a rotating shaft 10. In other words, the motor 8 is aligned with the fan 6. Furthermore, the cannon 32 comprises a first group 11 of nozzles 100 operatively associated with the tubular body 2 and arranged centrally with respect to the tubular body 2 itself according to a direction transverse to the direction of propagation P to spray a first fire extinguishing fluid in the internal part of the air flow.

In other words, the first group 11 of nozzles 100 is centrally arranged so as to define in correspondence with them a ring for the passage of the air flow between the first group 11 of nozzles 100 and the tubular body 2. In other words again, during operation, the air flow moving along the propagation direction P surrounds the first group 11 of nozzles 100 and then recomposes itself once this first group 11 of nozzles 100 has been passed.

Preferably, the first fluid comprises a mixture of water and foaming agent.

Advantageously, the first group 11 of nozzles 100 allows the internal part of the air flow to be loaded with the first nebulized fluid so as to mix this first fluid with the air. In fact, the nozzles 100 of the first group 11 nebulize the first fluid transforming it into micro particles of fluid.

In addition, the gun 32 comprises a support head 12 for the first group 11 of nozzles 100. In particular, this support head 12 comprises a support part 13 positioned in proximity to the inlet 3 and an ogive-shaped part 14 positioned in proximity to the outlet port 4. Even more particularly, the support head 12 comprises a plurality of support wings 15 extending radially from the support part 13 towards the tubular body 2 and connected to the latter. In other words, the support head 12 is positioned centrally with respect to the tubular body 2 according to a direction transversal to the direction of propagation P. In other words, the support head 12 is suspended in mid-air inside of the tubular body 2.

It should be noted that the support wings 15 are connected between the support part 13 and the tubular body 2 so as to keep the tubular body 2 in position.

Preferably, the support head 12 is inserted in the passage zone Z. In detail, the support head 12 extends along the direction of propagation P from the support part 13 to the ogive-shaped part 14.

Advantageously, the support part 13 of the support head 12 is shaped like a cylinder and is aligned with the shaft 10 along the direction of propagation P so as not to interfere with the air flow.

Furthermore, the nozzles 100 of the first group 11 are mounted on the ogive-shaped part 14. Therefore, the nozzles 100 of the first group 11 of nozzles 100 are suspended in mid-air inside the tubular body 2.

In detail, the ogive-shaped part 14 of the support head 12 has a plurality of holes 16 inside each of which a respective nozzle 100 of the first group 11 is inserted. In greater detail, each hole 16 develops along its own axis substantially parallel to the direction of propagation P. In other words, each hole faces the outlet port 4 of the tubular body 2. In other words, the nozzles 100 of the first group 11 spray the first fluid towards the outlet port. outlet 4 of the tubular body 2.

Furthermore, the nozzles 100 of the first group 11 have an adjustable orientation so as to orient the spray of water according to directions more or less angled with respect to the direction of propagation P.

In addition, the first group 11 of nozzles 100 comprises at least two sub-groups 17 of nozzles 100 spaced along the direction of propagation P. In particular, the nozzles 100 of each sub-group 17 are arranged annularly on the ogive-shaped part 14.

More particularly, each sub-group 17 of nozzles 100 defines a ring of nozzles 100 arranged around the ogive-shaped part 14. In addition, the sub-groups 17 are spaced from each other along the direction of propagation P. Consequently , the subgroups 17 of nozzles 100 define crowns with a diameter that is reduced along the direction of propagation P so as to follow the ogival shape.

Furthermore, the device 1 comprises at least two feed ducts 20 for the first fluid respectively connected to one or more respective subgroups 17 of nozzles 100 so as to separate the feed of the first fluid of some subgroups 17 with respect to others. In particular, the support head 12 has cavities inside the support head 12 which put a respective duct 20 in communication with the nozzles 100 of the corresponding group. More particularly, each internal cavity of the support head 12 is in fluid communication with one or more respective subgroups 17.

For example, in the preferred embodiment, the support head 12 comprises two separate internal cavities and three subgroups 17 of nozzles 100. A first internal cavity is in fluid communication with the two subgroups 17 closest to the outlet port 4 , while a second internal cavity is in fluid communication with the subgroup 17 of nozzles 100 closest to the inlet port 3.

Furthermore, each internal cavity is shaped like a tube and extends from the respective group of nozzles 100 to its own fluid inlet end 18 arranged laterally on the support head 12. In detail, the inlet end 18 is a hole made on the support head 12 at its own part closest to the outlet 4 of the tubular body 2.

Note that, during use, each supply duct 20 of the first fluid is connected to a respective inlet end 18 of the internal cavity (in figure 3c each inlet end 18 is shown disconnected from the relative supply duct 20) .

In this way, the supply of the fluid to each subgroup 17 can be selectively controlled according to the requirements in order to more or less charge the air flow with the particles of the first fluid.

Furthermore, the gun 32 comprises a second group 19 of nozzles 100 operatively associated with the tubular body 2 and arranged in a ring around the air flow to spray a second fire extinguishing fluid towards the air flow.

Preferably, the second fluid comprises a mixture of water and foaming agent.

In particular, the second group 19 of nozzles comprises a plurality of atomizing nozzles 100 arranged annularly at the outlet 4 of the tubular body 2.

Advantageously, the second group 19 of nozzles 100 allows the second fluid to be injected on the outermost part of the air flow in order to increase the area of action of the air flow. In particular, the second group 19 of nozzles 100 nebulizes the second fluid so as to generate a plurality of micro particles which are injected towards the air flow.

In fact, while the first group 11 of nozzles 100 injects the particles of the first fluid from the inside of the air flow giving it a certain consistency, the second group 19 of nozzles 100 sprays the particles of the second fluid from the outside towards the air flow. In this way, part of the particles of the second fluid penetrate the outgoing air flow and part remain suspended on the air flow and are dragged by the latter towards the fire to be extinguished.

In addition, the particles of the first fluid give consistency and weight to the air flow to have a predefined range, while the particles of the second fluid increase the area of action of the device 1 for the emission of a jet of fluid .

Furthermore, the second group 19 of nozzles 100 is arranged outside the overall dimensions of the tubular body 2 according to a direction transversal to the direction of propagation P. In detail, the second group 19 of nozzles 100 is arranged along a circumference having diameter substantially equal to the diameter of the tubular body 2. Preferably, the gun 32 comprises an annular duct 21 to which the nozzles 100 of the second group 19 are operatively connected. In detail, each nozzle 100 of the second group 19 is in fluid communication with the annular duct 21. The annular duct 21 is in turn connected to a supply duct 22 for the second fluid.

During use, the supply pipes 20, 22 of the first fluid and of the second fluid are connected to a supply source located upstream of the device 1 for the emission of a jet of fluid. Such a power source is not part of the present invention. In detail, the device 1 comprises a flexible duct 33 in fluid communication with said gun 32 and connectable to said fire-fighting fluid source.

Preferably, each nozzle 100 of the second group 19 comprises four fluid emission holes 23 (Figure 3).

As previously explained, the nozzles 100 of each group are of the nebulizing type. Advantageously, these nozzles 100 nebulizers transform the respective fluids into microscopic particles (drops) of fluid which are carried to the fire by the flow of air. In this way, the size of these particles favors the exchanges of temperature between them and the fire.

Therefore, during use, the microscopic particles of the fluids contained in the air flow that propagates outside the tubular body 2 cool the burning materials with which they come into contact in order to facilitate the extinguishing of the fire. Therefore, the fire is extinguished thanks to the joint action of the foam, which suffocates the flames, and of the atomized water which cools the burning objects by dampening the combustion.

In particular, the nebulized fluid is present both in the internal part of the air flow (thanks to the presence of the first group 11 of nozzles 100) and in the external part of the air flow (thanks to the presence of the second group 19 of nozzles 100) in order to lower the temperature of the fiery objects hit by the entire flow of air.

Furthermore, the device 1 comprises a water and foam mixer 24 in fluid communication with the first group 11 of nozzles 100 and with the second group 19 of nozzles 100 to send a mixture of water and foam to both groups. More precisely, the mixer 24 is connected to the first group 11 of nozzles 100 and to the second group 19 of nozzles 100 by means of the supply ducts 20 of the first fluid and the supply duct 22 of the second fluid.

In other words, each supply duct 20, 22 extends from the mixer 24 towards a respective group 11, 19 of nozzles 100.

Preferably, the mixer 24 is positioned upstream with respect to the tubular body 2 (and downstream with respect to the power source) and is removable with respect to the latter. It should be noted that, in the preferred embodiment, the first fluid and the second fluid comprise the mixture of water and foam. In a variant of the preferred embodiment, the first fluid and the second fluid comprise this mixture of water and foam in different percentages.

In an embodiment of the invention, illustrated in Figure 2, the device 1 for the emission of a jet of fluid optionally comprises a pump 39, associated with the flexible duct 33, so as to be able to raise the pressure of the fire-fighting fluid inside the flexible duct 33. In this way, it is possible to obtain finer fluid particles and thus optimize the nebulization of the fire extinguishing fluid. Therefore, the presence of the pump allows to increase the suspension time of the particles in the air (being finer they are also lighter) and to intensify the heat exchanges with the burning objects in order to reduce the extinguishing time of the fire.

Preferably, the pressure of the first fluid and of the second fluid in the presence of the pump is between 30 bar and 35 bar. While, in the preferred embodiment (and therefore without pump) the pressure of the first fluid and of the second fluid in the presence of the pump varies around 10 bar.

The device 1 also comprises means 25 for orienting the gun 32, in particular associated with the tubular body 2, for orienting the gun 32 towards the fire to be extinguished.

As previously mentioned, the device 1 comprises a frame 9 on which the gun 32 is mounted, in particular the tubular body 2. The orientation means 25 of the tubular body 2 are operatively interposed between the frame 9 and the gun 32.

In the preferred embodiment, the orientation means 25 comprise a first rotation member 26 with a horizontal axis 31 and a second rotation member 27 with a vertical axis.

The first rotation member 26 comprises an arcuate bar 28 fixed at its ends to the tubular body 2 and a support bridge 29. The arcuate bar 28 is rotatably mounted on the support bridge 29 and rotates around a horizontal axis 31 in so as to define the angle of inclination of the tubular body 2 with respect to the ground. Furthermore, the orientation means 25 comprise an extender member 30 connected between the arched bar 28 and the support bridge 29 to control the movement of the tubular body 2. The second rotation member 27 is preferably mounted between the first rotation member 26 and the frame 9 and allows the tubular body 2 to rotate around a vertical axis.

The device for the emission of a jet of fluid 1 further comprises a winding device 34 associated with the flexible duct 33 and connected to the cannon 32.

In particular, this winding device 34 comprises a support 35, preferably prismatic and even more preferably cylindrical. This support 35 is rotatable around its own rotation axis. The flexible duct 33 is connected to the support 35, in particular in correspondence with a peripheral area, in such a way that it can be wound and / or unwound around the support 35.

The winding device 34 also comprises at least one wall 36, located at a lateral end of the support 35. In particular, the device comprises a pair of walls 36 each located on an opposite end of the support 35. These walls lateral 36 define, in cooperation with the support 35, a recess in which the flexible duct 33 is housed when it is wound on the support 35. In other words, the walls 36 confine the flexible duct 33 to the support 35 and prevent it from falling sideways .

The device 1 also comprises a return member 37 associated with said winding device 34 to deflect the flexible duct 33. In particular, the return member 37 comprises a rod 38 arranged parallel to the axis of rotation of the support 35. More particularly, the rod is placed between the two walls 36 of the winding device 34.

The device for the emission of a jet of fluid 1 also comprises a return member (not shown) associated with the winding device 34. This return member is active on the support 35 so as to exert a torque on it which it tends to neatly wrap the flexible duct 33 and keep it taut.

Preferably, the organ of call is of the passive type. In detail, this return member is of the elastic type, and even more preferably it is a spring.

Alternatively, the recall organ is of the active type. In this case, the return organ is preferably an electric motor.

In an embodiment of the invention, shown in figure 1, the winding device 34 is fixed to the frame 9. Advantageously, this allows a more compact configuration of the device for the emission of a fluid jet 1. In fact, in this case the winding device 34 is fixed on the same frame 9 to which the gun 32 is also fixed.

In an alternative embodiment, shown in Figure 2, the device 1 comprises a trolley 40, which can be hooked to the frame 9. In particular, the trolley 40 is towed by the frame 9. In other words, the trolley 40 is detachably hooked to the frame 9. Advantageously, this allows to use the winding device 34 also together with a device for the emission of a jet of fluid 1 for which it was not foreseen in the construction and assembly phase. In other words, by connecting a trolley 40 to a frame 9, a device for the emission of a jet of fluid 1 according to the present invention is obtained.

As shown in Figures 1 and 2, the device 1 for the emission of a jet of fluid comprises means of locomotion 41 associated at least with the cannon 32. In detail, these means of locomotion 41 are connected to the frame 9 to move the cannon 32. Furthermore, the means of locomotion 41 are of the motor type.

In particular, in the embodiment illustrated in Figure 1, the means of locomotion 41 comprise tracks 44.

Alternatively, in the embodiment of Figure 2, the means of locomotion 41 comprise rubber wheels 42. If it is necessary to operate along a railway line, the means of locomotion 41 comprise iron wheels 43 for railway tracks. In particular, these iron wheels 43 are in addition or alternatively to the rubber wheels 42. If both types are present, (as shown in figure 2) the wire wheels 43 can be raised and / or lowered by means of suitable handling means for come into contact with the rails (not shown) excluding the use of rubber wheels 42.

Furthermore, it should be noted that the device 1 comprises further locomotion means 45 associated with the carriage 40 for its movement. Preferably, these further means of locomotion 45 can comprise rubber wheels 42 or iron wheels 43. In the preferred case of Figure 2, the further means of locomotion 45 comprise iron wheels 43.

Preferably, the further means of locomotion 45 are not motorized.

To control the device 1, a remote control (not shown) is provided in the preferred embodiment of the invention. The remote control is in particular associated with the means of locomotion 41 for controlling the movement of the tracks 44 and / or the driving wheels 42, 43. The remote control is also associated with the gun 32 to command its activation and / or deactivation and, advantageously, with the orientation means 25 for directing the gun 32.

In addition to or as an alternative to the remote control, the device 1 for the emission of a jet of fluid comprises a control panel (not shown) associated at least with the gun 32. More preferably, this control panel is also associated with the control means locomotion 41 and the means of orientation 25.

In the preferred embodiment of the invention, in order to reduce the dimensions of the device for the emission of a jet of fluid 1, neither a seat nor a steering wheel for an operator is included. In other words, when the device 1 for the emission of a jet of fluid includes the aforementioned control panel, it is preferably positioned on a rear side, in such a way as to be controlled by an operator standing even during the handling and / or operation of the gun 32.

Furthermore, it should be noted that device 1 does not include a tank for containing the fire extinguishing liquid (water and foam), but is suitable for connection to a fixed hydraulic system mounted near the fire place.

According to the preferred embodiment of the invention, the frame 9 and / or the gun 32 have a maximum width dimension of 2 meters and a maximum length dimension of 3 meters.

As far as the operation of the present invention is concerned, it follows directly from what has been described above.

In particular, once the tubular body 2 has been positioned, the fan 6 is activated and the first fluid and the second fluid are fed respectively to the first group 11 of nozzles 100 and to the second group 19 of nozzles 100.

In this way, the first group 11 of nozzles 100 cools the internal part of the air flow by charging it with particles of water and foam; while the second group 19 of nozzle 100 cools the external part of the air flow generating a trail of water and foam particles dragged by the air flow itself.

Therefore, thanks to the force of the fan 6, the air flow carries the nebulized fluids in correspondence with the fire to dampen it.

In practice, during use, the air flow, charged with nebulized particles, spreads from the tubular body 2 to the fire, forming an arc full of water and foam particles.

The present invention achieves the intended purposes. The presence of the winding device, in fact, is able to avoid the dragging of the flexible duct on the ground, in particular in operating conditions when it is full of water and therefore heavier. Consequently, the tears of this duct are prevented, which is therefore more reliable.

Furthermore, the device for the emission of a jet of fluid can be controlled by a remote control. As a result, it will not be necessary to include a seat to accommodate a driver, allowing for the construction of smaller sized fire extinguishing devices.

The invention also achieves important advantages. The present invention in fact decreases the extinguishing times of the fire thanks to the generation of a flow of air leaving the tubular body loaded with particles of water and foam. In fact, this air flow has a greater area of action than the known technique since the exit speed (and therefore the throw) of the air flow is dictated by the force of the fan and not by the speed of water as defined in the prior art.

Furthermore, the present invention decreases the extinguishing times of the fire as this extinguishing occurs both by suffocation of the flames, thanks to the presence of the foam in the air flow, and by combustion cooling, thanks to the presence of the nebulized fluids that they favor thermal exchanges.

It should also be noted that the present invention is relatively easy to realize and that also the cost connected to the implementation of the invention is not very high.

Claims (16)

CLAIMS 1. Device (1) for the emission of a jet of fluid characterized by the fact of comprising: a cannon (32) having an outlet mouth (4), said cannon (32) being configured to deliver a nebulized fluid through said outlet mouth (4); a flexible conduit (33) in fluid communication with said gun (32) and connectable to a source of fluid to bring, in use, the fire fighting fluid to the gun (32); a winding device (34) for the flexible duct (33) mounted on said gun (32). 2. Device (1) for the emission of a jet of fluid according to the preceding claim, characterized in that it comprises a return member (37) associated with said winding device (34) to divert said flexible duct (33) . 3. Device (1) for the emission of a jet of fluid according to any one of the preceding claims, characterized in that it comprises a return member associated with said winding device (34) to wind said flexible duct (33) and keep it taut. 4. Device (1) for the emission of a jet of fluid according to the preceding claim, characterized in that said return member is of the passive type, preferably elastic and even more preferably a spring. 5. Device (1) for the emission of a jet of fluid according to claim 3, characterized in that said return member is of the active type, preferably a motor and even more preferably of the electric type. 6. Device (1) for the emission of a jet of fluid according to any one of the preceding claims, characterized in that it comprises a pump (39) associated with said flexible duct (33) to raise the pressure of the fluid to the inside of said flexible conduit (33). 7. Device (1) for the emission of a jet of fluid according to any one of the preceding claims, characterized in that it comprises a frame (9) connected to said gun (32) and fixed to said winding device (34) . 8. Device (1) for the emission of a jet of fluid according to any one of claims 1 to 6, characterized in that it comprises a frame (9) connected to said gun (32); a trolley (40) hooked to said frame (9) to be pulled by said frame (9), said winding device (34) being fixed to said trolley (40). 9. Device (1) for the emission of a jet of fluid according to any one of the preceding claims, characterized in that it comprises locomotion means (41) associated with said cannon (32). 10. Device (1) for the emission of a jet of fluid according to the preceding claim, characterized in that said means of locomotion (41) comprise railway wheels (43). 11. Device (1) for the emission of a jet of fluid according to claim 9, characterized in that said means of locomotion (41) comprise tracks (44). Device (1) for the emission of a jet of fluid according to any one of the preceding claims, characterized in that it comprises orientation means (25) for the gun (32) to direct it towards the fire to be extinguished. 13. Device (1) for the emission of a jet of fluid according to any one of the preceding claims, characterized in that it comprises a remote control associated with said cannon (32) to remotely pilot said cannon and / or said means of locomotion ( 41). Device (1) for the emission of a jet of fluid according to any one of the preceding claims, characterized in that it comprises a control panel associated with said gun (32). 15. Device (1) for the emission of a jet of fluid characterized by the fact that said fluid is a fire-fighting fluid. Use of the device (1) according to claim 15 for extinguishing fires.