Motor Boat with Retractable Foils

Abstract

The invention relates to a motor boat comprising a bearing structure (1) and at least one foil (2) which is defined by a hydrofoil and its support (4), which is positioned under said structure and slideably mounted with respect to the latter; characterized in that the foil (2) is also mounted in such a way as to adopt at least two fixed positions, namely a position referred to as the active position in which the foil (2) is lowered and a position referred to as the passive position in which the foil (2) coincides with the bearing structure (1) or is fully retracted into the latter.

Claims

1-6. (canceled)

7. A motor boat comprising: a bearing structure and at least one foil including a wing and a support, which is arranged below the structure and slideably mounted with respect thereto, wherein the foil is configured to adopt at least two fixed positions including a position referred to as the active position in which the foil is lowered and a position referred to as the passive position in which the foil coincides with the bearing structure or is entirely retracted inside the latter.

8. The motor boat as claimed in claim 7, wherein the foil is configured to slide along a curved trajectory.

9. The motor boat as claimed in claim 7, wherein the foil is configured to slide when the boat is moving, while retaining a constant orientation with respect to the flow.

10. The motor boat as claimed in claim 7, wherein in the passive position, at least one part of the support is visible from the control station of the boat.

11. The motor boat as claimed in claim 7, further comprising: an automated system for positioning the foil as a function of various parameters such as the current position of the boat, desired actions, current or predicted meteorological conditions, etc.

12. The motor boat as claimed in claim 11, wherein the automated system comprises a dynamic simulator, for example of the DDP type, capable of predicting the dynamic behavior and the seakeeping under all navigation conditions.

Description

DESCRIPTION OF THE INVENTION

[0007] The present invention relates to a hybrid motor boat with foils, that is to say one being able to navigate in Archimedean configuration or to foil and change configuration during navigation. See FIG. 1.

[0008] The invention relates more precisely to a motor boat comprising a bearing structure and at least one foil, defined by a wing and its support, which is arranged below said structure and slideably mounted with respect thereto; characterized in that the foil is also mounted so as to adopt at least two fixed positions, namely a position referred to as the active position in which the foil is lowered and a position referred to as the passive position in which the foil coincides with the bearing structure or is entirely retracted inside the latter.

[0009] Preferably, but not exclusively, the boat according to the invention comprises the following elements, taken in isolation or in combination (cf. FIGS. 2 to 5): [0010] A bearing structure 1. [0011] At least one foil 2 and one stabilizer 3, possibly combined as a single bearing device (for example delta wing), which are arranged below the bearing structure 1 and adapted to bear on the water so as to support and balance the bearing structure 1 when the boat moves on the water, the foil 2 being slideably mounted with respect to the bearing structure 1, along a trajectory substantially perpendicular to the underside of the bearing structure 1, between, on the one hand, a position referred to as the active position where the foil 2 is lowered and, on the other hand, a passive position where the foil 2 is embedded in the bearing structure 1. [0012] A system for the sliding of a curved support 4 which makes it possible to rapidly switch from the passive position to the active position of the foils 4, the latter having to satisfy the autostability rules of so-called first-generation hydrofoils with traversing V foils 6. [0013] A system for the retractability of the foils 2 which is activatable when the boat is in operation, with the incidence of the foil 2 with respect to the flow remaining substantially identical throughout the action of rising or lowering of the foils 2. [0014] An improvement in the behavior and comfort onboard the boat by using automatic piloting and/or correction systems which act according to the parameters indicated by an onboard simulator, for example of the dynamic performance prediction (DPP) type which was developed by the applicant. This system in particular makes it possible to simulate the future behavior of the boat starting from a given equilibrium position and from new events (control action, state of the sea, wind, etc.).

[0015] Apart from the fact that the motor boat according to the invention offers all the advantages of a boat with foils (reduction in drag at high speed, improvement in onboard comfort in certain sea conditions, maneuverability) its change of configuration offers other advantages, in particular: [0016] Reduction in draft on approaching shallow waters. [0017] Reduction in drag at low speed. [0018] Reduction in the overall size of the boat (in particular the width) during maneuvers, circulation in limited spaces, storage. [0019] Docking similar in all respects to a conventional boat, without recourse to dedicated and complex logistics inherent to boats with foils, and more particularly to boats with traversing V foils termed first-generation hydrofoils. [0020] No restriction in the condition of use specific to a hydrofoil in the sense where the boat can at any time return to a retracted foil configuration and navigate in the same way and with the same limits as a conventional boat of the same category.

[0021] The foils can be housed in the hull in the upper position, behind a recess in the submerged part of the vessel, which also makes it possible to effectively reduce the drag induced by the foils when the boat is in the Archimedean configuration 7 (cf. FIG. 4).

[0022] According to another embodiment of the invention, the foils are guided by two blocks adapted in that they allow the passage of sails of varying chord and twist.

[0023] Advantageously, the system for mechanically raising the foils comprises a screw jack secured to the bearing structure and to the foil simultaneously.

[0024] The system for mechanically raising the rudders may comprise a screw jack secured to the bearing structure and to the foil simultaneously.

[0025] In a more general manner, any other lifting/lowering system (hydraulic jacks, pulley blocks, racks, etc.) can be used.

[0026] In order to improve the behavior of the boat and/or to optimize the performance thereof, the rudders can be controlled to rotate about the lateral axis. This system makes it possible either to modify the trim of the boat by bringing into incidence the bearing planes positioned at the bottom of the rudder 8 to pitch them up or to pitch them down in an identical manner, or to modify the rolling of the boat by asymmetrically modifying the incidences of the port-side and starboard-side bearing plates 9. Advantageously, the movements for controlling the pitching and the rolling can be coupled to provide a complete response to the dynamics of the desired movement. In this configuration, it is required to know the position of the boat. To this end, a gyrocompass can be installed onboard to measure the pitching and the rolling. The gyrocompass provides measurement information which can be converted into a control order to adjust the rotational positioning of the rudders. These operations can of course be automated 10. (FIG. 5).

[0027] In another preferred embodiment of the invention, use is made of a dynamic simulator 10, capable of predicting the dynamic behavior and the seakeeping under all navigation conditions. This simulator, known as a dynamic performance prediction (DPP) simulator and developed by the applicant, is used upstream in order to define and optimize the design of the boat (positions, profiles, characteristics, etc.). It also makes it possible to provide the parameters necessary for configuring the feedback loops of the onboard automatic pilots. Finally, advantageously, the simulator can be used in an onboard manner in order to provide directly the script to be executed by the automaton. In this mode of operation, the simulator is supplied with the information from the onboard sensors and permanently calculates the future states of the boat, which allows it to provide the appropriate instructions to the onboard controls to achieve the desired operating state which may be an attitude of the boat, a performance, the following of a programed route, a predefined driving mode etc.

[0028] Preferably, the automaton comprises a dynamic solver to convert the input from the gyrocompass into a rotational command on the rudders. The automaton is then capable of predicting the change in the forces on the boat and thus of incorporating into the command of the controller notions such as the geometry of the appendages or of the boat. In the present case, the autostable geometry of the foils allows the controller to reduce the oscillations and to reduce the time necessary to obtain the targeted state.

[0029] The dynamic solver solves the equations of the movement with six degrees of freedom. However, these equations can be simplified (linearization of the equations) as a function of the performance of the numerical resolution. The numerical scheme will preferably be an adapative time step scheme, although the performance of the resolution will adapt this choice and will be able to allow the use of a numerical scheme of the Runge-Kutta type or other methods of the scientific literature.

[0030] The models resolving the forces must be adapted to the craft controlled by the autopilot, and consequently the geometries of the boat must be introduced into the simulator by means of files of the CAO file or text file type of a suitable format.

[0031] Advantageously, the command order given by the automaton is transmitted to the rudders in the form of hydraulic power. A hydraulic pump converts the electrical command order from the automaton in the form of hydraulic pressure. Jacks convert the hydraulic power into rotational movement of the rudders and thus ensure that the behavior of the vehicle is optimized.

[0032] The command mode can also be provided by other means, electrical jacks, racks, etc.

[0033] The propulsive apparatus is included in bulbs at the bottom of the rudders 11. The propulsive apparatus must be permanently submerged both in Archimedean and deployed-foil configuration. It must additionally rise into an upper position, that is to say one closer to the bearing structure during the Archimedean configuration to reduce the draft.

[0034] The propulsive apparatuses receive the power supplied by the engine of the vehicle to the bottoms of the rudders. The rudders are translatable vertically so as to be able to be raised into an upper position. In order to advantageously transmit the power and provide the torque necessary for the boat to lift off, an engine, for example a combustion engine 12, coupled to hydraulic pumps 13 is installed. These hydraulic pumps lead the hydraulic power through the rudders by means of flexible hoses 14. The propulsive apparatus is composed of a hydraulic generator and of a propeller. FIG. 6.

[0035] Other systems for transmitting the power can also be used: hydrojet, propeller shaft with universal joints etc.

[0036] It goes without saying that the invention is not limited to the examples described and illustrated in the present document. It covers any type of mechanism which makes it possible to modify the position of the foils during navigation as defined in the claims.