ES1286659U - Propeller device (Machine-translation by Google Translate, not legally binding) - Google Patents

Abstract

Drive device comprising a rotor (14), a stator (15), an outer casing (6), a first base (10) with a central inlet opening (1) configured for a fluid intake, and an outlet opening (2) configured for an expulsion of propellant fluid in the form of an outlet jet, characterized in that the outlet opening (2) is located along the entire perimeter of the propellant device, where the propellant device comprises: - a valve central (3) configured, by means of tilting means, to tilt with a certain direction and tilt angle, thus regulating a flow rate of a fluid inlet jet and a direction of the fluid inlet jet towards a certain sector of the device propellant, and; - a perimeter valve (7) configured, by means of tilting means, to tilt with a certain direction and tilt angle, thus regulating a flow rate of the fluid outlet jet and a direction of the fluid outlet jet towards a certain sector of the perimeter outlet opening (2).

Description

DESCRIPTION

drive device

Object of the invention

The object of the present invention is a propulsion device that allows the thrust direction to be rapidly varied for the propulsion of boats.

The propulsive device object of the present invention can facilitate the implementation of autonomous water vehicles USV ( ünmanned Surfacing Vehicle) in closed environments such as ports or perform precision maneuvers.

The propellant device object of the present invention has application in the field of Naval Engineering and, more specifically, in the industry dedicated to the design, manufacture, marketing and operation of propulsion devices for various types of vessels, both surface and underwater.

Background of the invention and technical problem to be solved

Naval thrusters of the Voith-Schneider type are known in the state of the art. These propellers comprise a set of rotating propellers or blades mounted on a disk. Above the disk is the motor that produces the movement of translation of the propellers (through the rotation of the disk). Likewise, above the disk there is a set of two perpendicular pistons, joined to a set of connecting rods that allow the coordinated turning of the propellers, making them able to vary the angle of attack on the water in their movement of translation. By means of this variation of the angle of attack, an impulse of the water is produced that moves through the propellers in the desired direction, in any angle from 0° to 360° and, therefore, it is possible to direct the ship and propel it and vary its direction through a single device.

The Voith-Schneider propeller has a limitation derived from the cycloidal movement of the propellers. In propellers, the lower and upper surfaces of each blade reverse their position twice per revolution, going from inside to outside and vice versa; this translates into a tendency to cavitation that forces the propeller to rotate with a limited RPM value and develop a lower navigation speed. This situation produces a practical limitation of the speed of rotation of the propeller, if cavitation effects are to be avoided in the upper surface of the propeller located downstream in the direction of propulsion.

A propellant of the type described in document US 2010/0267295 A1 is also currently known. It is an azimuthal thruster that allows the impulsion jet to be directed along the 360° of its perimeter. One drawback of this type of thruster is that, to vary the thrust direction by 180°, the thrust jet must pass through all intermediate positions/angles. This can cause inaccuracies when maneuvering a vessel with this type of thruster, which may require additional maneuvering to correct the vessel's heading.

Description of the invention

In order to solve the aforementioned drawbacks, the present invention relates to a propelling device.

The propellant device object of the present invention comprises a rotor, a stator, an outer casing, a first base with a central inlet opening configured for a fluid intake, and an outlet opening configured for an expulsion of propellant fluid in the form of an outlet jet.

The aforementioned characteristics of the propellant device object of the present invention coincide with those of a propellant known in the state of the art, such as the propellant described in document US 2010/0267295 A1.

The propellant device object of the present invention has a novel configuration that avoids the drawbacks mentioned with respect to the propellant US 2010/0267295 A1. Thus, in a novel way, in the propulsion device object of the present invention, the outlet opening is located along the entire perimeter of the propulsion device.

Additionally, in a novel way, the propulsive device object of the present invention comprises:

- a central valve configured, by means of tilting means, to tilt with a certain direction and tilt angle, thus regulating a flow rate of a fluid inlet jet and a direction of the fluid inlet jet towards a certain sector of the device propellant, and;

- a perimeter valve configured, by means of tilting means, to tilt with a certain direction and tilt angle, thus regulating a flow rate of the fluid outlet jet and a direction of the fluid outlet jet towards a certain sector of the opening perimeter exit.

Thus, as can be seen, the propelling device object of the present invention does not need to redirect an outlet opening each time the thrust/propulsion direction is to be varied, passing through each and every one of the positions along the arc. of circumference that separates the direction of initial propulsion from the desired direction of propulsion.

The propelling device object of the present invention simply has to tilt the central valve and the perimeter valve to regulate both the inlet and outlet flows, as well as the directions of the inlet and outlet jets, towards the desired sector of the propellant device.

In this way, much faster and more precise turns of the boats are allowed, which is especially useful in closed environments and with limited dimensions such as ports, places where the precision in the maneuvers to be carried out by the boats acquires special importance. .

Preferably, the central valve tilting means comprise a piston mechanism configured to cause a lever to tilt according to a certain tilt angle and in a certain direction, where the lever is connected to the central valve.

Preferably, the perimeter valve tilting means also comprise the aforementioned piston mechanism and the lever.

This piston actuation mechanism has similarities to the aforementioned “Voith Schneider drive”, where a piston mechanism is also used. However, in the case of the "Voith Schneider propeller", this piston mechanism, which allows the direction of propulsion to be varied (as in the propellant device object of the present invention) is used to move a set of propellers, generating the drawbacks already mentioned.

According to possible embodiments of the propulsive device (see first and third embodiments described below) the perimeter valve is connected to the lever by means of a dome-shaped structure.

Alternatively, according to other possible embodiments (see second and fourth embodiments described below) the perimeter valve is connected by means of arms to the central valve.

Preferably, the drive device is configured so that the path of the fluid between the inlet opening and the perimeter outlet opening first passes through the rotor and then through the stator.

The stator may be arranged around the rotor, and, additionally, it may also be arranged to project in an axial direction parallel to a longitudinal major axis of the drive device, beyond a longitudinal dimension of the rotor.

Alternatively to what is mentioned in the previous paragraph, the stator can be arranged beyond a longitudinal dimension of the rotor, according to an axial direction parallel to a main longitudinal axis of the drive device. In this configuration, as seen in Figure 6, in Figure 7 and in Figure 8, the stator is arranged on the rotor overlapping the rotor in said longitudinal/axial direction. This configuration allows the rotor blades to have a larger surface area, which gives the propulsion device greater power.

The rotor and/or the stator may comprise variable pitch blades.

Preferably, in the propellant device object of the present invention, the perimeter valve comprises a flap arranged in a radial direction towards the interior of the propellant device. Thus, by regulating (thanks to the tilting of the perimeter valve) the space between said flap and a wall of a base body of the propelling device and an internal frame of the propelling device, the perimeter valve is configured to regulate respectively a first percentage of outgoing flux from the stator that is directed towards the perimeter outlet opening and a second percentage of outgoing flux from the stator that is directed through a return cavity, back towards the rotor. By means of the mechanism described here, it is possible to regulate the flow of the outlet jet, thus regulating the thrust or propulsion force of the propelling device, and it is possible to take advantage of the flow not used for propulsion, making it recirculate towards the rotor, conserving or increasing its Kinetic energy.

The drive device may comprise an annular outlet conduit connecting an outlet of the stator with the perimeter outlet opening of the drive device.

The annular outlet duct can connect with the perimeter outlet opening by means of an elbow-shaped geometry.

Preferably, the outer casing of the propellant device is flush with the first base (or lower base of the propellant device). This configuration makes it possible to attenuate the possible dispersion of the output jet of the propulsive device.

Preferably, the central valve of the propellant device has a convex curved geometry. This makes it possible to facilitate, by Coanda effect, the directing of the inlet flow through the inlet opening, directly towards the rotor inside the propulsion device, since the curvature of the central valve guides the inlet jet towards the rotor.

This is an advantage over known configurations of propellants (for example, the intake device for propellants described in document DE 102019106717 A1) in order to produce the aforementioned Coanda effect that helps to direct the inlet flow through the opening of central inlet, resort to a convex element consisting of a protuberance (“ Zustromwulst') that projects beyond the base of the propeller, which increases its draft, increasing hydrodynamic friction and reducing its efficiency.

By means of the configuration of the propulsive device described above, it is possible to direct the thrust jet only in the desired direction or to regulate its flow rate and time of opening and closing of the central valve (direction, intensity and frequency).

The propellant device object of the present invention is a high-precision naval propellant, specially developed to facilitate the automation of ships (with special application for USVs ( ünmanned Surface Vehicles) and UUVs ( ünmanned ünderwater Vehicles), which improves the operability of all types of vessels operating in the aquatic environment.

Brief description of the figures

As part of the explanation of at least one embodiment of the invention, the following figures have been included.

Figure 1: Shows a simplified and schematic bottom perspective view of the propelling device.

Figure 2: Shows a schematic sectional view of a first embodiment of the propellant device, with the central valve and the peripheral valve in the rest position.

Figure 3a: Shows a schematic view of the propellant device of Figure 2, where the central valve and the perimeter valve are shown with a minimum degree of inclination.

Figure 3b: Shows a schematic view of the propellant device of Figure 2, where the central valve and the perimeter valve are shown with an intermediate degree of inclination.

Figure 3c: Shows a schematic view of the propellant device of Figure 2, where the central valve and the perimeter valve are shown with a maximum degree of inclination.

Figure 4: Shows a schematic sectional view of a second embodiment of the propellant device, with the central valve and the peripheral valve in the rest position.

Figure 5: Shows a simplified and schematic bottom view, partially sectioned, of the rotor and stator of the drive device, according to the first embodiment or the second embodiment of the drive device.

Figure 6: Shows a schematic sectional view of a third embodiment of the propellant device, with the central valve and the peripheral valve in the rest position.

Figure 7: Shows a schematic sectional view of a fourth embodiment of the propellant device, with the central valve and the peripheral valve in the rest position.

Figure 8: Shows a simplified and schematic bottom view, partially sectioned, of the rotor and stator of the drive device, according to the third embodiment or the fourth embodiment of the drive device.

Figure 9a: Shows a bottom view of the propellant device, according to any of the embodiments, where fluid inlet and outlet flow lines are observed, corresponding to a minimum inclination of the lever and a minimum tilt of the central valve and the peripheral valve.

Figure 9b: Shows a bottom view of the propulsive device, according to any of the embodiments, where fluid inlet and outlet flow lines are observed, corresponding to an intermediate inclination of the lever and an intermediate tilt of the central valve and the perimeter valve.

Figure 9c: Shows a bottom view of the propelling device, according to any of the embodiments, where fluid inlet and outlet flow lines are observed, corresponding to a maximum inclination of the lever and a maximum tilt of the central valve and the perimeter valve.

Figure 10: Shows a simplified and schematic top view, partially sectioned, of the propellant device where the drive mechanism of the central valve and the perimeter valve can be seen.

Detailed description

The present invention relates, as mentioned above, to a propelling device.

The propellant device comprises a central fluid inlet opening (1) (or intake area) and a peripheral fluid outlet opening (2) (or expulsion area).

The central inlet opening (1) is located in the center of a first base (10) (or lower base, as shown in the Figures) of the propelling device.

The perimeter outlet opening (2) is preferably located on the perimeter of said first base (10) of the propelling device.

The propulsive device comprises an eminently cylindrical geometry, with a main axis (9) of radial symmetry perpendicular to the central inlet opening (1).

In correspondence with the central inlet opening (1), there is a central valve (3) with disc-shaped geometry.

The central valve (3) is actuated by a lever (4) linked to a piston mechanism (5).

Figure 10 shows a top view of the propulsion device, where the outer casing (6) has been sectioned at its upper part, exposing the piston mechanism (5).

de la palanca (4). Esta rótula

está conectada a un fulcro (17) o cojinete, con respecto al cual la palanca (4) puede bascular, como una unión articulada entre la rótula

de la palanca (4) y el fulcro (17).The lever (4) and the central valve (3) are connected through a ball joint

of the lever (4). this patella

is connected to a fulcrum (17) or bearing, with respect to which the lever (4) can tilt, as an articulated joint between the ball joint

of the lever (4) and the fulcrum (17).

By means of the movement of the pistons (5), the lever (4) is actuated in different directions, which produces the tilting of the central valve (3) in any direction, and according to different degrees of inclination.

The direction and tilt in which the central valve (3) can be tilted is determined by the length by which the pistons (5) of the piston mechanism (5) extend or retract. Preferably, the piston mechanism (5) comprises at least two pistons (5) arranged in mutually perpendicular directions.

By controlling the tilt direction of the central valve (3), it is possible to direct the intake flow in a preferred intake direction.

Likewise, by controlling the degree of inclination of the central valve (3), it is possible to control the inlet flow through the inlet opening (1) of the propulsion device.

Figure 1 shows a simplified bottom perspective view of the propelling device, according to any of the embodiments described in this document.

Figure 1 shows the propellant device with its outer casing (6), its central inlet opening (1) (or intake area) and its perimeter outlet opening (2) (or expulsion area). In correspondence with the inlet opening (1) the central valve (3) can be seen. Figure 1 shows some flow lines that schematically show the main direction of the input flow and the output flow, when the piston mechanism (5) actuates the lever (4) according to a certain direction and with a certain Inclination angle.

Figure 2 schematically represents a sectional view of the propelling device, according to a first embodiment thereof.

Figure 2 shows the perimeter valve (7) comprising a flap (8) projecting radially towards the center of the propellant device. In this first form of embodiment, the perimeter valve (7) is joined to the upper part of the lever (4) by means of a dome-shaped structure formed by a continuous surface or a dome-shaped network of ribs.

Figure 2 shows the propulsion device with the lever (4), the central valve (3) and the perimeter valve (7) in the rest position, that is, with the lever (4) inclined at 0° with with respect to the main axis (9) of the propelling device. In this position, the central valve (3) completely blocks the inlet opening (1) of the propellant device, and the flap (8) of the perimeter valve (7) completely blocks the outflow through the outlet opening ( 2) perimeter.

When the piston mechanism (5) begins to tilt the lever (4), the central valve (3) begins to tilt, causing the inlet opening (1) to remain open to the passage of fluid (typically water) towards a certain inner sector of the propulsive device.

Figure 3a shows the situation in which the central valve (3) of the propulsive device (according to the first embodiment) begins to tilt, allowing the fluid to enter through the inlet opening (1).

When the fluid enters the interior of the propulsion device through the inlet opening (1), it first passes through the rotor (14) and then through the stator (15).

Both in this first embodiment of the drive device and in the second embodiment of the drive device, the stator (15) is located around the rotor (14), projecting above the rotor (14) away from the first base (10) of the propelling device.

Both the rotor (14) and the stator (15) are located between a base body (11) of the drive device and an internal frame (13) of the drive device. The first base (10) of the propelling device is an outer face of said base body (11) of the propelling device.

At the outlet of the stator (15), the fluid flow can be directed towards a return cavity (16), back towards the rotor (14), or towards an annular outlet duct (18) connected to the outlet opening (2) perimeter. The annular outlet duct (18) runs between a wall (12) of the base body (11) and the outer casing (6) of the propelling device. The annular outlet duct (18) has a geometry substantially in the shape of a spherical or ellipsoidal crown truncated by two parallel planes. The connection area between the annular outlet duct (18) and the perimeter outlet opening (2) has a geometry that forms an elbow that forces the outlet flow of the propellant device to be directed centrifugally with respect to the main axis (9). ) of the propelling device.

However, according to alternative embodiments (not shown in the Figures) of the propulsion device object of the present invention, the propulsion device lacks an annular outlet duct (18) and the elbow-shaped connection area with the opening of exit (2) perimeter. In these alternative embodiments, the perimeter outlet opening (2) is directly the area that is located between the flap (8) of the perimeter valve (7) and the wall (12) of the base body (11), then being directly the outlet jet of the propulsive device the radial outlet of the stator (15).

In the situation shown in Figure 3a, the central valve (3) has started to tilt with a minimum tilt angle (which, in this case by way of example, is assumed to correspond to a 10° tilt of the lever (4). ) with respect to the main axis (9) of the propelling device). A small amount of fluid flow begins to access the interior of the propelling device, towards a certain first sector (S1) of the propelling device (see left area of Figure 3a), towards the rotor (14) of the propelling device. After passing through the rotor (14), the fluid is fired in all directions towards the stator (15). However, since the central valve (3) determines a main direction of the inlet flow towards the first sector (S1) of the propelling device, also most of the outlet flow of the rotor (14) is directed towards the outside of the rotor. (14) and towards the stator (15) in correspondence with said first sector (S1) of the drive device.

After passing through the stator (15), in correspondence with the first sector (S1) of the propulsive device, a small part of the flow exiting the stator (15) enters the annular exit duct (18) through the gap between the flap (8) of the perimeter valve (7) and the wall (12) of the base body (11). Subsequently, this small part of the flow exits in the form of an outlet jet from the propellant device through the perimeter outlet opening (2), in an area corresponding to the first sector (S1) of the propelling device. However, since the angle of inclination of the perimeter valve (7) with its flap (8) is minimal, most of the flow coming out of the stator (15) in said first sector (S1) is directed through the area located between the fin (8) of the perimeter valve (7) and the internal armature (13), towards the return cavity (16), back towards the rotor (14). Likewise, in sectors far away or opposite to the first sector (S1), the flap (8) of the perimeter valve (7) blocks the passage of fluid through the annular outlet conduit (18) towards the perimeter outlet opening (2), so that in said sectors remote or opposite to the first sector (S1), the flow at the outlet of the stator (15) is directed through the return cavity (16) back towards the rotor (14).

Thus, there is a situation where, with a minimum degree of inclination of the lever (4), the central valve (3) leaves a minimum passage of fluid towards the interior of the propelling device, and the perimeter valve (7) leaves a passage of fluid to the outside of the propellant device, thus having a minimal jet stream that produces low propulsion from the propellant device.

Figure 9a schematically shows the minimum outlet jet (corresponding to the minimum inclination of the lever (4) in Figure 3a) through flow lines through the perimeter outlet opening (2), in a zone corresponding to the first sector (S1) of the propelling device.

When it is desired to increase the magnitude or intensity of the propulsion produced by the propulsive device, the intake and expulsion in the propulsive device must be increased, thereby increasing the inlet and outlet flow. For this, it is necessary for the piston mechanism (5) to produce a greater inclination of the lever (4) with respect to the main axis (9) of the propelling device, which produces a greater tilting of the central valve (3) and the perimeter valve (7).

Figure 3b represents a situation of intermediate opening or tilting of the central valve (3) and the peripheral valve (7) (which, in this case, by way of example, is assumed to correspond to a 15° inclination of the lever ( 4) with respect to the main axis (9) of the drive device). This situation produces that, in the area of the propelling device corresponding to the first sector (S1), a greater proportion of the outgoing flow from the stator (15) enters through the gap between the flap (8) of the perimeter valve (7) and the wall (12) of the base body (11), towards the annular outlet duct (18) and outside the propelling device through the perimeter outlet opening (2). In contrast to this, in the area of the propelling device corresponding to the first sector (S1), a smaller proportion of the outgoing flow from the stator (15) enters the return cavity (16) through the area located between the fin (8) of the perimeter valve (7) and the internal armature (13), since by inclining the lever (4) more and thus tilting the perimeter valve (7) more, the space between the flap (8) and the armature is reduced interior (13) in the area corresponding to the first sector (S1) of the propulsive device.

As was the case when the inclination of the lever (4) with respect to the main axis (9) was minimal (Figure 3a), also in this situation of intermediate inclination of the lever (4), in sectors far away or opposite to the first sector. (S1) of the propelling device, the flap (8) of the perimeter valve (7) blocks the flow from the annular outlet conduit (18) to the perimeter outlet opening (2), so that in said remote or opposite sectors to the first sector (S1) of the drive device, the outflow from the stator (15) is directed through the return cavity (16) back towards the rotor (14).

In Figure 9b, the intermediate outlet jet (corresponding to the intermediate inclination of the lever (4) in Figure 3b) is shown schematically by means of flow lines through the perimeter outlet opening (2), in a zone corresponding to the first sector (S1) of the propelling device.

When it is desired to increase the magnitude or intensity of the propulsion produced by the propulsive device as much as possible, the intake and expulsion in the propulsive device must be maximized, thereby maximizing the inlet and outlet flow. To do this, it is necessary for the piston mechanism (5) to produce a maximum inclination of the lever (4) with respect to the main axis (9) of the propelling device, which produces a maximum tilt of the central valve (3) and the perimeter valve (7).

Figure 3c represents a situation of maximum opening or tilting of the central valve (3) and the peripheral valve (7) (which, in this case, by way of example, is assumed to correspond to a 20° inclination of the lever ( 4) with respect to the main axis (9) of the propelling device). This situation produces that, in the area of the propelling device corresponding to the first sector (S1), practically all of the outgoing flow from the stator (15) enters through the gap between the flap (8) of the perimeter valve (7) and the wall (12) of the base body (11), towards the annular outlet duct (18) and outside the propelling device through the perimeter outlet opening (2). In contrast to this, in the area of the propellant device corresponding to the first sector (S1), a practically null proportion of the outgoing flow from the stator (15) enters the return cavity (16) through the area located between the fin (8) of the perimeter valve (7) and the internal armature (13), since by tilting the lever (4) to the maximum and thereby tilting the perimeter valve (7) to the maximum, the space between the flap ( 8) and the inner frame (13) in the area corresponding to the first sector (S1) of the propelling device.

As was the case when the inclination of the lever (4) with respect to the main axis (9) was minimal (Figure 3a) or intermediate (Figure 3b), also in this situation of maximum inclination of the lever (4), in sectors away from or opposite the first sector (S1) of the propulsion device, the flap (8) of the perimeter valve (7) blocks the flow from the annular outlet conduit (18) to the perimeter outlet opening (2), so that in said sectors remote or opposite to the first sector (S1) of the propulsive device, the outgoing flux from the stator (15) is directed through the return cavity (16) back towards the rotor (14).

Figure 9c schematically shows the maximum outlet jet (corresponding to the maximum inclination of the lever (4) in Figure 3b) through flow lines through the perimeter outlet opening (2), in an area corresponding to the first sector (S1) of the propelling device.

As can be seen in Figure 9a, in Figure 9b and in Figure 9c, in sectors adjacent to the first sector (S1) of the propelling device, there is also a small dispersion of the exit jet of the propelling device through the opening of exit (2) perimeter. However, thanks to the tilting of the perimeter valve (7) with its flap (8), Most of the outgoing flow from the stator (15) is directed towards the outside of the drive device through the annular outlet duct (18) and the perimeter outlet opening (2), only in the area corresponding to the first sector (S1 ), since the perimeter valve (7) with its flap (8) blocks the outflow of flow through the perimeter outlet opening (2) in sectors away from the first sector (S1) of the propellant device. In order for this minimum dispersion of the outlet jet to occur, it is also desirable that the outer casing (6) of the propellant device be flush with the first base (10) of the propellant device, so that the annular outlet conduit (18) obliges to the flux leaving the stator (15) in sectors adjacent to the first sector (S1) to mix with the flux leaving the stator (15) in the first sector (S1), thereby correcting or attenuating the dispersion in the outlet jet.

Figure 4 shows a second embodiment of the propelling device object of the present invention. This second embodiment differs from the first embodiment in that the perimeter valve (7), instead of being attached to the upper part of the lever (4) by means of a dome-shaped structure, is attached by means of arms ( 19) to the central valve (3). In this way, when the piston mechanism (5) produces the inclination of the lever (4) and, in turn, the tilting of the central valve (3), this tilting of the central valve (3) also produces tilting. of the perimeter valve (7).

Figure 5 shows a bottom sectional view of the rotor 14 and stator 15 of the drive device, according to the first embodiment and the second embodiment of the drive device. It can be seen that the rotor (14) is arranged inside the stator (15).

Figure 6 shows a third embodiment of the propulsive device object of the present invention. This third embodiment is analogous to the first embodiment, but where the stator (15) is not located around the rotor (14), but only above the rotor (14).

Figure 7 shows a fourth embodiment of the propelling device object of the present invention. This fourth embodiment is analogous to the second embodiment, but where the stator (15) is not located around the rotor (14), but only above the rotor (14).

Figure 8 shows a bottom sectional view of the rotor 14 and stator 15 of the drive device, according to the third embodiment and the fourth embodiment of the drive device. It is observed that the rotor (14) overlaps the stator (15).

In the third embodiment and in the fourth embodiment of the drive device, this arrangement of the rotor (14) with its blades having a larger surface area than in the first and second embodiments, and superimposed on the stator blades ( 15) in the longitudinal/axial direction, gives the propulsion device greater power.

In the third and fourth embodiments of the drive device, the flux leaving the rotor (14) and entering the stator is in the longitudinal/axial direction of the drive device (in the direction of the main axis (9) of the drive device) . In contrast to this, in the first and second embodiments of the drive device, the flux leaving the rotor (14) and entering the stator is in the radial direction of the drive device (in the direction perpendicular to the main axis (9) of the propelling device).

Preferably, the central valve (3) has a convex curved geometry, so that the admission of fluid towards the interior of the propellant device is favored by the Coanda effect that it produces in the intake jet, which tends to reproduce the geometry curve of the central valve (3), heading towards the rotor (14) of the propelling device. This Coanda effect is produced in the 360° of the central valve (3) so that, whatever the direction and tilt angle of the central valve (3), this Coanda effect is produced on the intake flow, favoring the fluid inlet directly to the rotor (14) of the propelling device.

The propulsive device object of the present invention allows to vary the direction and frequency of opening/closing (opening and closing time) of the central valve (3), as well as the intensity of the propulsion jet (by regulating the speed of rotation (RPM) of the rotor (14) and the opening of the perimeter valve (7)).

Preferably, the rotor 14 is configured with variable pitch blades.

Claims (15)

1. Drive device comprising a rotor (14), a stator (15), an outer casing (6), a first base (10) with a central inlet opening (1) configured for a fluid intake, and an opening outlet (2) configured for an expulsion of propellant fluid in the form of an outlet jet, characterized in that the outlet opening (2) is located along the entire perimeter of the propellant device, where the propellant device comprises: - a central valve (3) configured, by means of tilting means, to tilt with a determined tilting direction and angle, thus regulating a flow rate of a fluid inlet jet and a direction of the fluid inlet jet towards a certain propulsive device sector, and; - a perimeter valve (7) configured, by means of tilting means, to tilt with a certain direction and tilt angle, thus regulating a flow rate of the fluid outlet jet and a direction of the fluid outlet jet towards a certain sector of the perimeter outlet opening (2). 2. Propulsion device according to claim 1, characterized in that the pivoting means of the central valve (3) comprise a piston mechanism (5) configured to produce an inclination of a lever (4) according to a determined angle of inclination and in a certain direction, where the lever (4) is connected to the central valve (3). 3. Propulsion device according to claim 2, characterized in that the tilting means of the perimeter valve (7) comprise the piston mechanism (5) and the lever (4). 4. Drive device according to claim 3, characterized in that the perimeter valve (7) is connected to the lever (4) by means of a dome-shaped structure. 5. Propulsion device according to claim 3, characterized in that the perimeter valve (7) is connected by means of arms (19) to the central valve (3). 6. Drive device according to any of the preceding claims, characterized in that it is configured so that the path of the fluid between the inlet opening (1) and the perimeter outlet opening (2) first passes through the rotor (14) and then the stator (fifteen). Drive device according to claim 6, characterized in that the stator (15) is arranged around the rotor (14). Drive device according to claim 7, characterized in that the stator (15) is arranged projecting in an axial direction parallel to a longitudinal main axis (9) of the drive device, beyond a longitudinal dimension of the rotor (14). Drive device according to claim 6, characterized in that the stator (15) is arranged beyond a longitudinal dimension of the rotor (14), in an axial direction parallel to a main longitudinal axis (9) of the drive device. 10. Drive device according to any of the preceding claims, characterized in that the rotor (14) and the stator (15) comprise variable pitch blades. 11. Propulsion device according to any of claims 6 to 10, characterized in that the perimeter valve (7) comprises a flap (8) arranged in a radial direction towards the interior of the propulsion device, where by regulating the space between said flap ( 8) and a wall (12) of a base body (11) of the drive device and an internal frame (13) of the drive device, the perimeter valve (7) is configured to respectively regulate a first percentage of outgoing flow from the stator (15 ) that is directed towards the perimeter outlet opening (2) and a second percentage of outgoing flux from the stator (15) that is directed through a return cavity (16) back towards the rotor (14). Drive device according to any of claims 6 to 11, characterized in that it comprises an annular outlet conduit (18) connecting an outlet of the stator (15) with the peripheral outlet opening (2) of the drive device. Drive device according to claim 12, characterized in that the annular outlet duct (18) connects with the perimeter outlet opening (2) by means of an elbow-shaped geometry. Drive device according to any of the preceding claims, characterized in that the outer casing (6) is flush with the first base (10). 15. Propulsion device according to any of the preceding claims, characterized in that the central valve (3) has a convex curved geometry.