FR2825679A1 - Hydro-jet for boat propulsion includes hollow electric motor with hydraulic screw mounted in axial thrust bearings - Google Patents

Abstract

The hydro-jet includes a hydraulic screw (7) and a helico-axial pump (8) with the output fluid flow emerging through diffusers (9). A nozzle (10) completes the assembly. A hollow electric motor drives the hydraulic screw assembly. The hydro-jet comprises a propeller assembly including a hydraulic screw (7) which supplies a helico-axial pump (8) with the output emerging through diffusers (9). A nozzle (10) completes the assembly. Water is supplied via lateral louvers (6). A hollow electric motor is used, and this is provided with either an axial or a radial structure (11R, 11S) in order to drive the hydraulic screw assembly. The shaft (3) of the screw assembly is mounted on hydraulic thrust bearings (4V, 4R). The hydro-jet assembly may be mounted to turn in a pod attached to the outside of a vessel, or may be integral to the vessel.

Description

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HYDROJET NACELLE SHIP PROPELLER
AND DRIVEN BY A HOLLOW ELECTRIC MOTOR
DESCRIPTION
Field of the invention
The invention relates to the field of propulsion of submersible and unsinkable ships, by means of submerged propellants, outside the hull, for example under or next to the hull of a submersible ship, such as a boat. , or on either side of the hull of a submarine. It relates more particularly to such a hydrojet propulsion unit, driven by an electric motor.

Prior art and problem posed
In the field of ship propulsion, submersible or unsinkable, it is known to use several propulsion techniques using fully submerged propulsion nacelles. Among these, there is the propulsion by hydraulic jets, commonly called hydrojet o. Such a technique is illustrated by the French patent application of the same applicant of the present application and published under the number 2 766 262. This technique uses the principle of the reaction, the water being sucked by a water intake placed in front of the nacelle. A high-efficiency pump, placed inside the latter, communicates energy to the water to propel it outside under

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 the shape of a jet, by a nozzle, thus creating a thrust which propels the ship. As such a nacelle can be oriented in azimuth, the direction of propulsion can be chosen by the rotation of said nacelle. This type of propellant therefore allows a ship to perform any maneuver in port, to stabilize on the way or to do dynamic positioning, without the use of another mechanism. Such a nacelle can also be oriented around a horizontal axis to allow the attitude or the depth of a submarine to be changed.

 On the other hand, in a second type of propulsion by submerged nacelle, one can also cite the French patent application of the same applicant, published under the number 2 768 119, which describes a naval propellant with central propeller and asynchronous discoid motor. Such a propellant consists mainly of a central hub surrounded by the blades of a propeller around which is fixed the electric rotor of discoid shape and a sheath carrying bearings. The stator is placed on either side of the electric rotor, around the bearings. In other words, the electric motor surrounds the pipe inside which the propeller is located and through which the water flow passes. However, this type of propellant does not have an excellent performance, is very noisy and subject to the problems of cavitation.

 The object of the invention is to propose a third type of submerged naval propellant placed in a nacelle, while avoiding the drawbacks linked to these two types of propellants.

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Summary of the invention
The main object of the invention is therefore a ship propellant, in a nacelle, using both the hydrojet technique and propulsion by a hollow electric motor, that is to say surrounding the propellant hydraulic elements and the propelled water flow. It mainly includes a nacelle inside which are the following elements: - an electric motor; - a rotating propulsion unit driven by the electric motor; - an outlet nozzle, fixed to the rear of the nacelle, downstream of the rotating propulsion assembly; and - rectifiers attached to the nacelle.

 The propellant is characterized according to the invention in that the rotating propulsion assembly consists of: a hydraulic screw; and - a helical-axial pump placed downstream and integral with the hydraulic screw; and in that the electric motor is of the hollow type, that is to say having a rotor and a stator of relatively large diameter and pierced in their central part, in order to surround the rotating propulsion assembly, so that the rotor is fixed around the rotating propulsion assembly, in order to drive it in rotation.

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 In the preferred embodiment of the invention, the motor rotor is placed around the hydraulic screw.

 To make the water penetrate inside the nacelle and in particular upstream of the hydraulic screw, it is planned to use inlet gills placed laterally.

 In the main mechanical embodiment of the rotating propulsion assembly, it is mounted on a shaft itself mounted rotating in the nacelle by bearings and hydraulic stops.

 According to the invention, the electric motor can be of two types, a first which is of the radial field type, the motor being of large external diameter, the second being of the axial field type, and being of the same internal diameter, but of longer length.

List of Figures
The invention and its various technical characteristics will be better understood on reading the following description, given by way of example, and illustrated with two figures representing respectively: FIG. 1, in section, a first embodiment of the propellant according to the invention, equipped with an axial electric motor; and Figure 2, in section, a second embodiment of the propellant according to

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 the invention, equipped with a radial electric motor.

Detailed description of two embodiments of the invention
FIG. 1 represents the propellant according to the invention, equipped with an electric motor with an axial field, that is to say with a rather elongated shape around the axis 1 of the propellant. Inside a nacelle 2 is therefore mounted rotating a shaft 3, by means of hydraulic thrust bearings 4V and 4R, mounted respectively in a front part 2V and a rear part 2R of the nacelle 2. At the level of the front end 3V of the shaft 3, that is to say downstream of the front part 2V of the nacelle 2, there is an inlet chamber 5 equipped with several openings 6 placed laterally with respect to the axis 1 of the propellant. Water is therefore sucked in through these vents 6 to penetrate the inlet of a rotating propulsion assembly supported by the shaft 3.

 Around the latter is fixed a hydraulic screw 7. At the output of the latter, the internal shape of the nacelle 2 widens to form a convex toric channel around the rear part 2R of the nacelle 2. In the first part which flares out of the curved channel, the blades 8 of a helical-axial pump are secured to the shaft 3. They are followed, in the second part which tightens up the curved channel, by rectifiers 9 fixed to the nacelle

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 2. The propellant's hydraulic circuit ends with a nozzle 10 fixed to the nacelle 2.

 The electric motor is of the type immersed in water and is placed axially around the hydraulic screw 7. The stator lily is integral with the nacelle 2, while the rotor 11R is fixed around the hydraulic screw 7 and is therefore integrated on the rotating propulsion assembly. The stator lily and the rotor 11R are jacketed. The motor can be either synchronous or asynchronous.

 The 4V and 4R thrust bearings are of the hydraulic type, more precisely they are permanently supplied with water in which the nacelle is located, under pressure.

 FIG. 2 represents the propellant according to the invention in an embodiment using a motor of the radial type, that is to say that the electric field is radial. Consequently, its outside diameter is slightly larger than that of the axial motor used in the embodiment described in FIG. 1. On the other hand, its length is shorter.

 The nacelle 12 is similar to the nacelle 2 in FIG. 1 and the rotating propulsion assembly is almost identical. The screw, the vanes 8 of the axial-axial pump, the rectifiers 9 and the nozzle 10, are identical. It is the same for the shaft 3 of the rotating propulsion assembly which is also mounted rotating, by thrust bearings 4V and 4R in respective parts before 12V and rear 12R of the nacelle 12.

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 On the other hand, the start of the hydraulic course is a little different in the sense that the inlet chamber 15 is a little more elongated, gills 16 being however also placed laterally.

 The motor therefore comprises a discoid rotor 21R fixed around the hydraulic screw 17. It is placed between the two parts 21S of the stator which are fixed relative to the nacelle 12.

Advantages of the propellant according to the invention
Several advantages are inherent in the hydrojet propulsion technique. Indeed, at equal power, a propeller propeller rotates approximately at 150 revolutions / minute, while a hydrojet propellant rotates approximately at 600 revolutions / minute. The size of the motors being inversely proportional to the speed of rotation, the motor, used in a hydrojet technique, is much more compact than that used to drive a propeller.

 It is advantageous to couple two propellers, that is to say two hydrojet assemblies, on the same nacelle. Indeed, this makes it possible to cancel the torque on the nacelle orientation system if the two groups are working, one in dextrorotatory rotation, and the other in senestrogyre rotation, the two couples canceling out.

 At high speeds, propeller thrusters tend to experience cavitation. This phenomenon causes noise and risks of damage to the

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 blade level, unlike the hydrojet propulsion system, which does not cavitate.

 The use of hydraulic thrust bearings makes it possible not to use ball bearings. This reinforces resistance to shocks, in particular to military shocks.

 From the point of view of acoustic discretion, propulsion by hydrojet has many advantages. Indeed, the type of pump, the speed, the fact that it is force-fed by a hydraulic screw and that the water flow takes place in a confined channel are all advantages compared to the propeller which turns in open environment and at low frequency. The same is true for the use of hydraulic thrust bearings, replacing noisy ball bearings.

 The propellant according to the invention does not require a ventilation, lubrication or cooling aid. The reverse thrust is done as on conventional hydrojets with a concave deflector, maneuvered by a jack.

 The efficiency of a helical-axial pump, used in the propellant according to the invention, associated with a hydraulic screw which feeds the inlet of the helical-axial pump, is of the order of 75%. We can therefore consider an increase of 10% on the overall propulsion efficiency compared to a traditional propeller.

 The use of propulsion by hydrojet, and in particular by double hydrojet, can be integrated harmoniously in the water lines and in the shapes of the ship's hull. In this case, it

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 therefore finds much less overhang than a propeller, detached from the hull of the ship in a nacelle mounted at the end of a mast. Hydraulic drag and tactical vulnerability are considerably reduced.

 It is possible to use four thrusters according to the invention on the same steerable platform, this solution promotes integration into the hull.

Claims (6)

1. Ship propeller in a nacelle by hydrojet and using an electric motor, comprising: - a nacelle (2, 12): - an electric motor (llR, 11S, 21R, 21S) placed in the nacelle; - a rotating propulsion unit (16,17, 8,9) driven by the rotor of the electric motor; and - an outlet nozzle (10), fixed to the rear of the nacelle (2.12), downstream of the rotating propulsion assembly; and - rectifiers (9) fixed to the nacelle (2, 12), characterized in that the rotating propulsion assembly comprises: - a hydraulic screw (7,17); and - a helical-axial pump (8) placed downstream and integral with the hydraulic screw (7,17), and in that the electric motor is of the hollow type, that is to say having a rotor (11R, 21R) and a stator (11S, 21S) of large diameter and drilled in their central part in order to surround the rotating propulsion assembly and so that the rotor (llR, 11S) is fixed around the rotating propulsion assembly.  2. Ship thruster according to claim 1, characterized in that the rotor (llR, 11S) is placed around the hydraulic screw (7,17). <Desc / Clms Page number 11>  3. ship thruster according to claim 1, characterized in that it comprises lateral vents (6,16) for the entry of water into the rotating propulsion assembly.  4. ship thruster according to claim 1, characterized in that the rotating propulsion assembly is mounted on a shaft (3) mounted rotating in the nacelle (12) by hydraulic thrust bearings (4V, 4R).  5. Ship thruster according to claim 1, characterized in that the electric motor (11R, 11S) is in the axial field.  6. ship thruster according to claim 1, characterized in that the electric motor (21R, 21S) is in the radial field.