EP3976463B1 - Automatic variable pitch propeller - Google Patents

Description

This patent application claims the priority of the French patent application FR19/05753 which will be considered as an integral part of this description.

Technical area

The present description generally concerns variable pitch propellers and, more particularly, a device for controlling the pitch of a variable pitch propeller. This description applies in particular to variable pitch propeller thrusters.

Prior art

Propeller thrusters are already widely used to set machines in motion, typically to navigate boats, to fly aircraft, etc. For example, motorized propeller thrusters are usually fitted to small boats capable of traveling over a wide range of speeds. Where applicable, these thrusters are often equipped with variable pitch propellers, so that the pitch of the propeller increases as the speed of the boat increases. This makes it possible to maintain a substantially constant engine speed whatever the speed of the boat. This improves the efficiency of the propellant.

Changing the pitch of the propeller of a controllable pitch propeller thruster is generally carried out automatically. The thruster then includes a system for controlling the pitch of the propeller in relation, typically, to the speed of the boat and/or in relation to a motor torque applied to a propeller shaft.

Among the most common propeller pitch control systems, we find hydraulic, electrical, mechanical or hydrodynamic systems. These systems, often expensive and very sensitive to operate, are also complex to design and build. Their development raises, in particular, numerous waterproofing issues. In addition, they generally do not make it possible to obtain satisfactory control of the propeller pitch over the entire speed range of the boat.

There are, in addition, manually controlled propeller pitch servo systems. These manual systems, although often less complex than the automatic systems mentioned above, nevertheless require very delicate adjustment on the part of the pilot of the boat. Manual propeller pitch modification systems are therefore, in practice, difficult to use, which makes them difficult to use by a wide audience.

The document US 6,358,007 describes a universal constant speed variable pitch boat propulsion system.

The document WO 2007/016804 describes a boat engine.

The document US 5,219,272 describes a variable pitch marine thruster with hydrodynamic variation. The document JP S 59126798 U describes a variable pitch marine thruster with another example of a variation mechanism.

Summary of the invention

There is a need to improve the existing pitch control devices of a variable pitch propeller.

One embodiment overcomes all or part of the drawbacks of known pitch control devices for a variable pitch propeller.

The invention provides a device comprising a variable pitch propeller and means adapted to modify the pitch of the propeller by Venturi effect.

According to the invention, an external flow of a fluid generates, by Venturi effect, a depression in a first compartment of a chamber comprising one or more first orifices not parallel to an axis of rotation of the propeller, a variation of this depression causing a movement of a movable partition inside the chamber activating a mechanism for modifying the pitch of the propeller.

• une hélice à pas variable ;
• une chambre comportant un ou plusieurs premiers orifices non parallèles à un axe de rotation de l'hélice ;
• une cloison mobile délimitant, à l'intérieur de la chambre, un premier compartiment communiquant avec l'extérieur par ce ou ces premiers orifices ; et
• un mécanisme de modification du pas de l'hélice, associé à la cloison mobile.

One embodiment provides a device comprising:

• a variable pitch propeller;
• a chamber comprising one or more first orifices not parallel to an axis of rotation of the propeller;
• a movable partition delimiting, inside the chamber, a first compartment communicating with the outside through this or these first orifices; And
• a mechanism for modifying the pitch of the propeller, associated with the movable partition.

According to one embodiment, a variation of a depression in the first compartment causes a modification of the pitch of the propeller.

According to one embodiment, an increase in depression causes an increase in the pitch of the propeller.

According to one embodiment, a reduction in depression causes a reduction in the pitch of the propeller.

According to one embodiment, at least one additional part forms, relative to an external surface of the chamber, a constriction in the vicinity of this or these first orifices.

According to one embodiment, the movable partition further delimits, inside the chamber, a second compartment communicating with the outside through one or more second orifices parallel to the axis of rotation of the propeller.

According to one embodiment, the movable partition is linked to a return spring towards a position corresponding to an extreme value of the pitch of the propeller.

According to one embodiment, the movable partition is a piston comprising an inclined surface, relative to the axis of rotation of the propeller, on which rests a cam adapted to actuate the mechanism for modifying the pitch of the propeller. helix.

According to one embodiment, the movable partition is associated with a gear, consisting of a rack and a pinion, adapted to actuate the mechanism for modifying the pitch of the propeller.

According to one embodiment, the propeller pitch modification mechanism modifies a blade pitch angle over an angular range less than 90°, preferably of the order of 15°.

According to one embodiment, the propeller comprises at least two blades arranged radially and separated from the axis of rotation by a distance of approximately 35 mm, preferably equal to 35 mm, these blades having a length of approximately 240 mm , preferably equal to 240 mm.

One embodiment provides a propulsion device comprising a device as described.

One embodiment provides a human-powered boat comprising at least one propulsion device as described.

One embodiment provides an energy recovery device, comprising a device as described.

Brief description of the drawings

• la figure 1 illustre de façon schématique et partielle, par une vue latérale et en coupe, un mode de réalisation d'un propulseur à hélice à pas variable automatique ;
• la figure 2 illustre de façon schématique et partielle, par une vue latérale et en coupe, un autre mode de réalisation d'un propulseur à hélice à pas variable automatique ;
• la figure 3 illustre de façon schématique et partielle, par des vues (A) et (B) latérales et en coupe, encore un autre mode de réalisation d'un propulseur à hélice à pas variable automatique ;
• la figure 4 représente, par des vues (A) et (B) en perspective et en écorché, encore un autre mode de réalisation d'un propulseur à hélice à pas variable automatique ;
• la figure 5 représente un exemple d'embarcation équipée d'un propulseur à hélice à pas variable automatique ; et
• la figure 6 représente, de façon partielle, un mode de réalisation d'une hélice de propulseur.

These characteristics and advantages, as well as others, will be explained in detail in the following description of particular embodiments given on a non-limiting basis in relation to the attached figures, among which:

• there figure 1 illustrates schematically and partially, in a side view and in section, an embodiment of an automatic variable pitch propeller thruster;
• there figure 2 illustrates schematically and partially, in a side view and in section, another embodiment of an automatic variable pitch propeller thruster;
• there Figure 3 illustrates schematically and partially, through side and sectional views (A) and (B), yet another embodiment of an automatic variable pitch propeller thruster;
• there Figure 4 represents, through perspective and cutaway views (A) and (B), yet another embodiment of an automatic variable pitch propeller thruster;
• there figure 5 represents an example of a boat equipped with an automatic variable pitch propeller propeller; And
• there Figure 6 partially represents an embodiment of a thruster propeller.

Description of embodiments

The same elements have been designated by the same references in the different figures. In particular, the structural and/or functional elements common to the different embodiments may have the same references and may have identical structural, dimensional and material properties.

For the sake of clarity, only the steps and elements useful for understanding the embodiments described have been represented and are detailed.

Unless otherwise specified, when we refer to two elements connected to each other, this means directly connected without intermediate elements other than conductors, and when we refer to two elements connected or coupled to each other, this means that these two elements can be connected or be linked or coupled via one or more other elements.

In the following description, when referring to absolute position qualifiers, such as "front", "back", "up", "down", "left", "right", etc., or relative, such as the terms "above", "below", "superior", "lower", etc., or to qualifiers of orientation, such as the terms "horizontal", "vertical", etc., it Unless otherwise specified, reference is made to the orientation of the figures or to a boat or propeller in a normal position of use.

Unless otherwise specified, the expressions "approximately", "approximately", "substantially", and "of the order of" mean to the nearest 10%, preferably to the nearest 5%.

The embodiments described take for example a propeller fitted to a thruster. However, these embodiments apply more generally to any variable pitch propeller system in which similar problems arise, for example wind turbines or tidal turbines.

There figure 1 illustrates schematically and partially, in a side view and in section, an embodiment of a thruster 1 with an automatic variable pitch propeller.

According to this embodiment, the propeller 1 comprises a propeller 11 consisting of two blades 111 and 112. The blades 111 and 112 are arranged in opposition, perpendicular to an axis 113 of rotation of the propeller 11. The axis 113 of rotation of propeller 11 is, in figure 1 , parallel to the cutting plane. The blades 111 and 112 are pivotally mounted relative to a common axis 115, perpendicular to the axis 113 of rotation of the propeller 11. To facilitate understanding, the axis 115, around which the blades 111 and 112 of the propeller pivot 'helix 11, is, in figure 1 , oriented perpendicular to the cutting plane.

A pivoting (or rotation) of the blades 111 and 112, around the axis 115, makes it possible to vary the pitch of the propeller 11 of the propeller 1. In particular, the pivoting, relative to the axis 115, of the blade 111 of the propeller 11 modifies a pitch angle θ, or angle of attack, of the blade 111. Likewise, the pivoting, relative to the axis 115, of the blade 112 of the propeller 11 modifies a pitch angle α, or angle of attack, of the blade 112. The propeller 1 is therefore equipped with a propeller 11 with variable pitch. In other words, the thruster 1 is a variable pitch thruster.

The angle θ corresponds, in this example, to an angle formed by a chord (straight line joining a leading edge to a trailing edge of a profile) of the blade 111 relative to a normal to the axes 113 and 115. Likewise, the angle α corresponds, still in this example, to an angle formed by a chord of the blade 112 relative to a normal to the axes 113 and 115. According to a preferred embodiment, the angle α of setting of the blade 112 has a value equal to that of the pitch angle θ of the blade 111. This makes it possible to balance the rotation of the propeller 11 around the axis 113, thus limiting the appearance of vibrations.

• d'un éventuel mouvement du milieu dans lequel se trouve le propulseur (courant du fluide) ;
• du profil (ou géométrie) des pales 111 et 112 ;
• d'une vitesse ω de rotation (ou vitesse angulaire) de l'hélice 11 autour de l'axe 113 ; et
• du pas de l'hélice 11, c'est-à-dire des angles θ et α de calage respectivement modifiés par pivotement (flèche 116) des pales 111 et 112 autour de l'axe 115.

Assuming that we look at the thruster 1 from its rear part towards its front part (from the right towards the left, in figure 1 ), a rotation of the propeller 11 in a clockwise direction (arrow 114) causes a flow (arrow 116, FLOW) of a fluid towards the rear of the propeller 1 at a speed v. The speed v of this flow depends in particular:

• a possible movement of the medium in which the propellant is located (fluid current);
• the profile (or geometry) of the blades 111 and 112;
• a speed ω of rotation (or angular speed) of the propeller 11 around the axis 113; And
• of the pitch of the propeller 11, that is to say the pitch angles θ and α respectively modified by pivoting (arrow 116) of the blades 111 and 112 around the axis 115.

The speed ω of rotation of the propeller 11 is, for example, imposed by a motor driving a shaft connected to the propeller 11. In the example of the figure 1 , the more the angles of attack α and θ increase, for a speed ω of rotation assumed to be constant, and the more the speed v of the flow increases.

In the example of the figure 1 , the thruster 1 comprises a body 13 in which a cavity (or recess) forming a chamber 15 is arranged. The body 13 of the thruster 1 has one or more orifices 131 not parallel to the axis 113 of rotation of the propeller 11. In figure 1 , for example, two orifices 131 are made in a direction perpendicular to the axis 113 of rotation of the propeller 11. The orifices 131 thus form through holes which open into the interior of the chamber 15.

According to one embodiment, the chamber 15 comprises a first compartment 151 separated from a second compartment 153 by a movable partition 17 or piston. In the example of the figure 1 , the first compartment 151 communicates, via the two orifices 131, with the exterior of the chamber 15. The second compartment 153 of the chamber 15 is, as for it, completely enclosed and therefore does not communicate with the outside of room 15.

In the example of the figure 1 , the propeller 1 is immersed in a fluid, for example water, constituting an external environment where the chamber 15 and the propeller 11 are placed in particular. The first compartment 151 of the chamber 15 is therefore, in figure 1 , filled with water. Water exchanges can thus occur freely, via the orifices 131 (or water intakes), between the interior and exterior of the chamber 15. The second compartment 153 is, still in this example, preferably filled with a gas, for example air. The movable partition 17 ensures, where appropriate, a dynamic seal between the first compartment 151 and the second compartment 153, so that the air contained in the second compartment 153 thus remains trapped there whatever the position of the movable partition 17. .

We consider a flow of fluid along the body 13, for example caused by a movement of the propeller 1 in the medium, typically under the effect of a rotation, around the axis 113, of the two blades 111 and 112 of the propeller 11. Such a flow causes, by Venturi effect, a depression inside the first compartment 151 of the chamber 15. Assuming that a pressure P1 reigns in the first compartment 151 and that a pressure P3 reigns in the second compartment 153, the value of the pressure P1 then decreases (the depression increases) as the water flow speed v increases. Conversely, the value of the pressure P1 increases (the depression decreases) as the water flow speed v decreases.

The pressure P3 is chosen or adjusted such that at rest, that is to say for a zero flow speed v, the pressure P3 is lower than the pressure P1. The movable partition 17 thus occupies, for a zero speed v, a fallback position located near the front of propeller 1 (on the left, in figure 1 ).

It is assumed that the pressure P1 decreases, by increasing the speed v, until it becomes lower than the pressure P3. The movable partition 17 is then pushed (or sucked) towards the rear of the propeller 1 (towards the right, in figure 1 ). This jointly causes, by increasing the volume of the second compartment 153, a reduction in the pressure P3. This reduction in pressure P3, opposing the reduction in pressure P1, tends to bring the movable partition 17 towards the front of the propeller 1 (towards the left, in figure 1 ). The movable partition 17 therefore stops in an intermediate position allowing the pressures P1 and P3 to balance or compensate each other.

We now assume that the pressure P1 increases, by decreasing the speed v, until it becomes greater than the pressure P3. The movable partition 17 is then brought towards the front of the propeller 1 (towards the left, in figure 1 ). This jointly causes, by reducing the volume of the second compartment 153, an increase in the pressure P3. This increase in pressure P3, opposing the increase in pressure P1, tends to push the movable partition 17 towards the rear of the propeller 1 (towards the right, in figure 1 ). The movable partition 17 therefore stops in another intermediate position allowing the new pressures P1 and P3 to balance or compensate each other.

In summary, pressures P1 and P3 both tend to move piston 17 in opposite directions. The piston 17 therefore stops, at non-zero speed v, in a position resulting from a dynamic equilibrium established between the pressures P1 and P3.

According to the embodiment presented in relation to the figure 1 , the movable partition 17 includes a rack 171 arranged parallel to the axis 113 of rotation of the propeller 11. On this rack 171 a pinion 173 meshes. The pinion 173 is, in figure 1 , held integral with the blade 111 of the propeller 11. The rack 171 is mounted such that a movement of the movable partition 17 towards the rear of the propeller 1 (towards the right, in figure 1 ) causes an increase in the pitch angle θ of the blade 111. A similar mechanism (not shown), making it possible to modify the angle α of the blade 112 of the propeller 11, is also implemented.

As mentioned previously, an increase in the speed v leads, by Venturi effect, to a reduction in the pressure P1 in the first compartment 151. This thus causes a movement of the movable partition 17 towards the rear of the propeller 1 (towards the right , in figure 1 ). This movement of the movable partition 17 tends, via the gear consisting of the rack 171 and the pinion 173, to increase the angle θ of attack of the blade 111. Likewise, a reduction in the speed v leads, by Venturi effect, to an increase in the pressure P1 in the first compartment 151. This thus causes a movement of the movable partition 17 towards the front of the propeller 1 (towards the left, in figure 1 ). This movement of the movable partition 17 tends, via the rack 171 and the pinion 173, to reduce the angle θ of attack of the blade 111. Similar modifications take place, thanks to the movement of the movable partition 17, on the angle α of attack of the blade 112. The movement of the piston 17 in the chamber 15 between extremal positions thus leads to modifying the angles of attack θ and α over an angular range less than 90°, from preferably around 15°.

We can therefore, by Venturi effect, automatically modify the angle of attack of the blades 111 and 112 by function of the speed v of water flow around the propeller 1. In other words, the movable partition 17 makes it possible, by moving, to control the pitch of the propeller 11 as a function of the speed v. The thruster 1 is therefore equipped with a propeller 11 with automatic variable pitch. In other words, the thruster 1 is an automatic variable pitch thruster.

Alternatively, the medium in which the propellant 1 is placed is air. The first compartment 151 of the chamber 15 is, where appropriate, filled with air. A flow of air along the body 13 of the propeller 1 causes, by Venturi effect, a depression in the first compartment 151. This depression tends, as explained previously, to shift the piston 17 towards the rear of the propeller 1 (towards the right, in figure 1 ), therefore to increase the pitch of the propeller 11.

There figure 2 illustrates schematically and partially, in a side view and in section, another embodiment of a propeller 2 with an automatic variable pitch propeller.

The thruster 2 of the figure 2 includes common elements with the propeller 1 of the figure 1 . These common elements will not be detailed again below.

The thruster 2 of the figure 2 differs from propeller 1 of the figure 1 mainly in that the propeller 2 comprises at least one additional or additional part 135. This part 135 forms, relative to an external surface of the chamber 15, a constriction 137 tightening in the vicinity of the orifices 131. The constriction 137 is, in figure 2 , accentuated by a particular geometry (or curve, or shape) of the body 13 of the propeller 2 near the orifices 131. The part 135 is, for example, a crown surrounding the body 13 and fixed to the propeller 2 in several places (not shown in the sectional view).

The restriction 137 is adapted to locally accelerate the flow of the fluid in the vicinity of the orifices 131. In other words, the fluid flows locally, in the vicinity of the orifices 131, at a speed greater than the overall speed v of the flow. This local acceleration of the flow makes it possible to accentuate the Venturi effect and thus increase the depression produced inside the first compartment 151 of the chamber 15. In the example of the figure 2 , the pressure P1 prevailing in the first compartment 151 of the propellant 2 will therefore, at equal flow speed v, be lower than the pressure P1 reigning in the first compartment 151 of the propellant 1 ( figure 1 ).

• le premier compartiment 151 communique, via les deux premiers orifices 131, avec l'extérieur de la chambre 15 ; et
• le deuxième compartiment 153 communique, via les deux deuxièmes orifices 133, avec l'extérieur de la chambre 15. Le deuxième compartiment 153 est alors, en figure 2, empli non plus d'air comme en figure 1, mais d'eau.

According to a preferred embodiment, the propeller 2 also comprises, in addition to the two first orifices 131, one or more second orifices 133 parallel to the axis 113 of rotation of the propeller 11. figure 2 , for example, two second orifices 133 are made in the thruster 2. The orifices 133 thus form through holes (or water intakes) which open into the interior of the chamber 15. When the thruster 2 is immersed, exchanges water can thus be produced freely, via the orifices 131 and 133, between the interior and exterior of the chamber 15. In the example of the figure 2 :

• the first compartment 151 communicates, via the first two orifices 131, with the exterior of the chamber 15; And
• the second compartment 153 communicates, via the two second orifices 133, with the exterior of the chamber 15. The second compartment 153 is then, in figure 2 , no longer filled with air as in figure 1 , but water.

The second orifices 133 make it possible, when the flow speed v increases, to increase the pressure P3 reigning inside the second compartment 153 of the chamber 15. This results in an increase in the speed v causes not only a reduction, by Venturi effect, of the pressure P1, but also an increase of the pressure P3. In the example of the figure 2 , the pressures P1 and P3 therefore both tend to move the piston 17 in the same direction, here towards the rear of the propeller 2 (towards the right, in figure 2 ), unlike the example of figure 1 where the pressures P1 and P3 tend to move the piston 17 in opposite directions.

• d'une part sur une surface du piston 17 délimitant le premier compartiment 151 de la chambre 15 ; et
• d'autre part sur une face interne du compartiment 151 située à l'arrière du propulseur 2.

In order to constrain or limit this movement of the piston 17, the propeller 2 of the figure 2 is, in addition, provided with a return spring 19, for example, with non-contiguous turns. The return spring 19 is arranged along the axis 113 of rotation of the propeller 11. This spring 19 is supported:

• on the one hand on a surface of the piston 17 delimiting the first compartment 151 of the chamber 15; And
• on the other hand on an internal face of compartment 151 located at the rear of propeller 2.

The spring 19 thus tends, by a restoring force directed parallel to the axis 113, to push the movable partition 17 towards the front of the propeller 2 (towards the left, in figure 2 ), in other words towards a position corresponding to an extreme value of the pitch of the propeller 11. The extreme value of the pitch of the propeller 11 is equivalent, in figure 2 , at a minimum step value also called “small step”.

• d'une part les pressions P1 et P3, qui tendent à repousser le piston 17 vers l'arrière du propulseur (vers la droite, en figure 2) ; et
• d'autre part la force exercée par le ressort 19 de rappel, qui tend à ramener le piston 17 vers l'avant du propulseur (vers la gauche, en figure 2).

We thus return to an operation equivalent to that of the figure 1 , except that the piston 17 stops, for each speed v, in a position resulting from a dynamic equilibrium no longer established between the pressures P1 and P3 only, but between:

• on the one hand the pressures P1 and P3, which tend to push the piston 17 towards the rear of the propeller (towards the right, in figure 2 ) ; And
• on the other hand the force exerted by the spring 19 of return, which tends to bring piston 17 towards the front of the propeller (towards the left, in figure 2 ).

At zero speed v, the pressures P1 and P3 are approximately equal. The position of piston 17 is then located at the front of propeller 1 (on the left, in figure 2 ), that is to say in the position which corresponds to the small pitch of the propeller 11. When the speed v increases, the piston 17 compresses the spring 19 by moving towards a corresponding position, in figure 2 , at a maximum value of the pitch, also called “large pitch”, of the propeller 11.

An advantage of the embodiment presented in relation to the figure 2 lies in the fact that the pitch of the propeller 11 of the propeller 2 is regulated by a force of hydrodynamic origin, linked one-to-one to the speed of the flow.

Another advantage of the embodiment of the figure 2 compared to that of the figure 1 is that it overcomes the constraint of maintaining a dynamic seal between the compartments 151 and 153 of the chamber 15. The compartments 151 and 153 can, in fact, exchange small quantities of water, at regard to the volumes of compartments 151 and 153, without this disrupting the operation of the mechanism for modifying the pitch of the propeller 11. This makes it possible in particular to relax possible precision constraints in the manufacture of the chamber 15 and of piston 17.

The propellant described in figure 1 or 2 further comprises a mechanism for automatically modifying the pitch of the propeller 11 consisting of a small number of components. This thruster 2 is therefore generally simpler to design, produce and develop than existing automatic variable pitch thrusters.

There Figure 3 illustrates schematically and partially, through side and sectional views (A) and (B), yet another embodiment of a propeller 3 with an automatic variable pitch propeller.

The thruster 3 of the Figure 3 includes common elements with the propeller 2 of the figure 2 . These common elements will not be detailed again below.

The thruster 3 of the Figure 3 differs from propeller 2 of the figure 2 mainly in that it is devoid of the gear consisting of the rack 171 ( figure 2 ) and pinion 173 ( figure 2 ).

According to this embodiment, the piston 17 has an inclined surface 175, or inclined pan, relative to the axis 113 of rotation of the propeller. A cam 177 is adapted to carry (or roll, or slide) against the surface 175 to actuate the mechanism for modifying the pitch of the propeller 11. In the example of the Figure 3 , the cam 177 is mounted at one end of a lever 179. The other end of the lever 179 is held integral with the blade 111 of the propeller 11, or with the pivot axis 115. In other words, the gear consisting of the rack 171 ( figure 2 ) and pinion 173 ( figure 2 ) is replaced, in Figure 3 , by the inclined surface 175 of the piston 17, the cam 177 and the lever 179.

Views A and B show different pitch positions.

We consider, initially (view A), that the propeller 11 of the thruster 3 rotates at a speed ω around the axis 113. The fluid flows towards the rear of the thruster 3 (arrow 116) at a speed v1, for example under the effect of a movement of the propeller 3 caused by the rotation of the propeller 11. The blade 111 then forms, relative to a normal to the axes 113 and 115, a certain pitch angle θ1. Likewise, the blade 112 then forms, relative to a normal to the axes 113 and 115, a certain pitch angle α1.

To simplify, we subsequently consider that the pitch angle of the blade 111 is always equal to the pitch angle of the blade 112. We are thus only interested in variations in the pitch angle of the blade. blade 111, variations in the pitch angle of blade 112 taking place by a similar mechanism.

We then assume that the flow speed increases (view B) to reach a value v2 greater than v1. The piston 17 then moves, as explained in relation to the figure 2 , towards the rear of the propeller 3 (arrow 118), thus compressing the spring 19. Thanks to the inclined plane 175, the end of the lever 179 on which the cam 177 is mounted therefore approaches the axis 113. This causes a rotation (arrow 120) of the blade 111 around the axis 115. In view B, the blade 111 then forms, relative to a normal to the axes 113 and 115, a new pitch angle θ2 greater than the setting angle θ1 (view A). Likewise, the blade 112 then forms, relative to a normal to the axes 113 and 115, a new pitch angle α2 greater than the pitch angle α1 (view A).

A thruster such as the thruster 3 is particularly suitable for equipping low-power boats, for example human-powered boats, where maximum efficiency from the propeller 11 is sought. We can then easily adapt the regulation of the pitch of the propeller 11 according to the physical capabilities of a user of the boat, for example by installing a spring 19 having a different stiffness constant, or by modifying the shape of the cam 177.

There Figure 4 represents, through perspective and cutaway views A and B, yet another embodiment of a propeller 4 with an automatic variable pitch propeller.

Views A and B show different pitch positions.

The thruster 4 of the figure 4 includes common elements with the propeller 3 of the Figure 3 . These common elements will not be detailed again below.

The thruster 4 of the figure 4 differs from propeller 3 of the Figure 3 mainly in that piston 17 drives a drawer 47 in translation. This drawer 47 actuates a lever 45 connected to the blade 111. Another lever 45 (not shown) is also connected to the blade 112.

The body 13 of the propeller 4 is, in Figure 4 , consisting of a hub 130 fitting into a cone 132. On the cone 132 is fixed the part 135 making it possible to accentuate the depression, caused by the Venturi effect, in the vicinity of the first orifices 131. The propeller 11 is fixed on a propeller shaft 43 passing through a mounting part 41 to the system with which it is associated, for example a boat (not shown).

The propeller 4 is, in view A, shown in a position where the spring 19 is relaxed. This position corresponds to the small pitch of propeller 11.

The propeller 4 is, in view B, shown in a position where the spring 19 is completely compressed. This position corresponds to the large pitch of propeller 11.

There figure 5 represents an example of a boat equipped with an automatic variable pitch propeller propeller.

In the example of the figure 5 , a boat 7 (for example, a human-powered boat or pedal boat) comprises at least one propeller 4 with an automatic variable pitch propeller, for example a single propeller 4. The propeller 4 is fixed to a hull 71 of the boat 7 The boat 7 is provided with a transmission 73 adapted to modify the rotation speed of the propeller 11 of the propeller 4. The boat 7 also has foils 77 or profiled wings adjustable via a control device 75 or feeler 75 making it possible to gauge the depth of the boat 7 relative to the surface of the water.

The propeller 4 allows the boat 7 to sail on the water. When the boat 7 is sailing, the propeller 4 is placed in a flow of water whose overall speed v is equal to a speed of movement of the boat 7 on the water. The pitch of the propeller 11 of the propeller 4 is thus adapted or controlled as a function of the speed of movement of the boat 7. This allows, for example, a user of the boat 7, causing the rotation of the propeller 11 with the strength of his legs, to maintain a substantially constant pedaling cadence whatever the speed of movement of the boat 7.

There Figure 6 represents, partially, an embodiment of a thruster propeller 11.

According to this embodiment, the blade 111 of the propeller 11 has dimensions adapted according to the application. The blade 112, partially represented in Figure 6 , preferably has dimensions identical to those of the blade 111. For a human-powered boat, such as the boat 7 ( figure 5 ), the blade 111 has a length, denoted LP, of approximately 240 mm, preferably equal to 240 mm.

It is assumed that the propeller 11 rotates, at an angular speed ω, around an axis 113 of rotation, as explained previously in relation to the figures 1 to 5 . A lower end 1111 of the blade 111 is arranged, relative to this axis of rotation 113, at a distance, denoted DA, of approximately 35 mm, preferably equal to 35 mm. Likewise, a lower end 1121 of the blade 112 is arranged, relative to the axis of rotation 113, at a distance DA of approximately 35 mm, of preferably equal to 35 mm. In other words, the lower ends 1111 and 1121 of the blades 111 and 112, respectively, are approximately equidistant from the axis of rotation 113, preferably equidistant from the axis of rotation 113. The lower ends 1111 and 1121 are also called “blade roots”.

• un grand pas géométrique d'environ 1 m, correspondant à des angles de calage θ2 et α2 (figure 3, vue (B)) approximativement nuls ; et
• un petit pas géométrique d'environ 0,67 m, correspondant à des angles de calage θ1 et α1 (figure 3, vue (A)) approximativement égaux à -10°.

A quantity, called "geometric pitch", is defined as being equal to a distance theoretically traveled by the propeller 11 when its blades 111 and 112 make a complete revolution around the axis of rotation 113. The geometric pitches of the propeller 11 are as follows:

• a large geometric step of approximately 1 m, corresponding to setting angles θ2 and α2 ( Figure 3 , view (B)) approximately zero; And
• a small geometric step of approximately 0.67 m, corresponding to pitch angles θ1 and α1 ( Figure 3 , view (A)) approximately equal to -10°.

• en grand pas, une poussée d'environ 110 N pour une vitesse de rotation ω d'environ 400 tr/min, ce qui correspond, pour l'embarcation 7, à une vitesse de déplacement approximativement égale à 20 km/h ; et
• en petit pas, une poussée d'environ 120 N pour une vitesse de rotation ω d'environ 400 tr/min, ce qui correspond, pour l'embarcation 7, à une vitesse de déplacement approximativement égale à 10 km/h.

The propeller 11, installed on the propeller 4 of the boat 7, thus makes it possible to achieve:

• in large steps, a thrust of approximately 110 N for a rotation speed ω of approximately 400 rpm, which corresponds, for the boat 7, to a speed of movement approximately equal to 20 km/h; And
• in small steps, a thrust of approximately 120 N for a rotation speed ω of approximately 400 rpm, which corresponds, for the boat 7, to a speed of movement approximately equal to 10 km/h.

Various embodiments and variants have been described. Those skilled in the art will understand that certain characteristics of these various embodiments and variants could be combined, and other variants will appear to those skilled in the art. In particular, the implementation of any type of mechanism likely to transform the translational movement of the piston 17 in a pivoting movement of the blades 111 and 112 around their axis 115 is within the reach of those skilled in the art from the indications provided above.

Finally, the practical implementation of the embodiments and variants described is within the reach of those skilled in the art based on the functional indications given above. In particular, it is possible to extend the embodiments described above to a configuration where the propeller 11 has a number of blades greater than two.

Claims (15)

1. Device comprising a variable-pitch propeller (11), a chamber (15), a movable partition (17) and a mechanism for modifying the pitch of the propeller (11) wherein an external flow (116) of a fluid generates, by Venturi effect, a negative pressure in a first compartment (151) of said chamber (15) comprising one or more first holes (131) not parallel to a rotation axis (113) of the propeller (11), a variation in this negative pressure causing a displacement of said movable partition (17) inside the chamber actuating said mechanism for modifying the pitch of the propeller (11).
2. Device according to claim 1, comprising:

   a variable-pitch propeller (11);

   a chamber (15) having one or more first holes (131) not parallel to a rotation axis (113) of the propeller (11);

   a movable partition (17) delimiting, inside the chamber (15), a first compartment (151) communicating with the outside via these one or more first holes (131); and

   a mechanism for modifying the pitch of the propeller (11), associated with the movable partition (17).
3. Device according to claim 2, wherein a change in vacuum in the first compartment (151) causes a change in the pitch of the propeller (11).
4. Device according to claim 1 or 3, wherein an increase in vacuum causes an increase in the pitch of the propeller (11).
5. A device according to any one of claims 1, 3 or 4, wherein a reduction in vacuum causes a reduction in the pitch of the propeller (11).
6. Device according to any one of claims 1 to 5, wherein at least one additional part (135) forms, with respect to an external surface of the chamber (15), a constriction (137) in the vicinity of these one or more first holes (131).
7. Device according to any one of claims 1 to 6, wherein the movable partition (17) further delimits, inside the chamber (15), a second compartment (153) communicating with the outside via one or more second holes (133) parallel to the rotation axis (113) of the propeller (11).
8. Device according to any one of claims 1 to 7, wherein the movable partition (17) is linked to a spring (19) for return to a position corresponding to an extreme value of the pitch of the propeller (11).
9. Device according to any one of claims 1 to 8, wherein the movable partition (17) is a piston comprising a surface (175) inclined, with respect to the rotation axis (113) of the propeller (11), on which a cam (177) is supported, adapted to actuate the mechanism for modifying the pitch of the propeller (11).
10. A device according to any one of claims 1 to 9, wherein the movable partition (17) is associated with a gear, consisting of a rack (171) and pinion (173), adapted to actuate the mechanism for modifying the pitch of the propeller (11).
11. Device according to any one of claims 1 to 10, wherein the mechanism for modifying the pitch of the propeller (11) modifies an angle (θ, α; θ1, α1; θ2, α2) of blade (111, 112) pitch over an angular range of less than 90°, preferably of the order of 15°.
12. Device according to any one of claims 1 to 11, wherein the propeller (11) comprises at least two blades (111, 112) radially arranged and separate from the rotation axis (113) by a distance (DA) of approximately 35 mm, preferably equal to 35 mm, these blades having a length (LP) of approximately 240 mm, preferably equal to 240 mm.
13. Propulsion device (1; 2; 3; 4) comprising a device according to any one of claims 1 to 12.
14. A human-powered boat (7) comprising at least one propulsion device as claimed in claim 13.
15. Energy recovery device, comprising a device according to any one of claims 1 to 12.

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