This application relates to a boat that comprises drives that have propellers each positioned in a duct ensuring optimized operation when making headway and high maneuverability.
The document FR-3,020,337 proposes a boat with hybrid propulsion that comprises a combustion drive and two electric drives placed on both sides of the combustion drive. Each electric drive comprises a propeller, positioned in a longitudinal duct, which extends from a water intake to a water outlet provided at the aft section of the boat. According to a special feature indicated in this document, each water intake is positioned in such a way as to be below the surface of the water when the boat sails at a speed below a given threshold and to be above the surface of the water when the boat lifts and sails at a speed in excess of the given threshold.
This embodiment is not completely satisfactory because it does not offer high maneuverability, in particular for carrying out certain maneuvers in port.
The document U.S. Pat. No. 5,090,929 proposes a boat equipped with two electric drives that are symmetrical relative to the median line of the hull and that each have a propeller positioned in a duct. Each duct comprises a first cylindrical and rectilinear section, which leads onto the transom of the boat and in which is positioned the propeller, as well as a second rectilinear section that leads, at a first end, onto the wall of the boat, and, at a second end, into the first section forward of the propeller. The second section leads onto the wall via louvered panels, oriented vertically, which orient the incoming stream of water in the direction of the propeller.
According to an embodiment, the boat comprises two drives at the bow for propelling the boat when making sternway and two drives at the aft section for propelling the boat when making headway.
According to this document, the electric drives are controlled by a single lever.
Even if this arrangement contributes to improving the maneuverability, the presence of four drives tends to complicate the boat design and therefore to increase its cost. According to another problem, the presence of the drives at the bow greatly tends to disrupt the flow of water along the hull when the boat is making headway and therefore to reduce the performance of the boat's propulsion system when making headway.
The purpose of this invention is to eliminate the drawbacks of the prior art.
For this purpose, the invention has as its object a boat that comprises at least one hull, a transom, at least two walls, as well as a propulsion system that comprises at least one internal combustion engine, positioned on or symmetrically relative to the vertical median plane of the boat, as well as at least two electric drives placed symmetrically relative to the vertical median plane and that each comprise a propeller placed in a duct that has:
According to the invention, the duct has the following characteristics:
The fact that the duct comprises at least one converging nozzle in the direction of a flow that passes from the side opening to the rear opening makes it possible to optimize the performance for a movement forward. The fact that the stream exiting from the side opening forms an angle of between 20 and 60° relative to the wall makes it possible, when a single electric motor propels a stream of water toward the bow, to create a resulting force that effectively makes the boat rotate, and, when the electric motors simultaneously propel streams of water toward the bow, to move the boat back effectively. Finally, the fact that the front section has a continuous curved profile makes it possible to reduce the pressure drops and to optimize performance regardless of the direction of travel.
According to other characteristics of the invention, the duct has at least one of the following characteristics:
Other characteristics and advantages will emerge from the following description of the invention, a description provided only by way of example, with regard to the accompanying drawings, among which:
According to an embodiment provided by way of example that is non-limiting and shown in
Each hull 12.1 and 12.2 comprises a transom 16.1 and 16.2, an outside wall 18.1 and 18.2, and an inside wall 20.1 and 20.2 that meet at a forward point 22.1 and 22.2.
The platform 14 comprises a bottom 24 that extends between the two hulls, a transom 26 placed approximately in the same plane as the transoms 16.1 and 16.2 of the hulls, as well as sides 28.1 and 28.2 that respectively top the outside walls 18.1 and 18.2.
The elements of the hull of the boat 10 are symmetrical relative to a vertical median plane PMV that is shown in
The invention is not limited to catamarans. Regardless of the embodiment, the boat 10 comprises at least one symmetrical hull relative to the vertical median plane, at least one transom, and two outside walls that are approximately parallel to the longitudinal direction at the aft section of the boat.
Preferably, the boat 10 comprises at least two hulls 12.1, 12.2 that are tapered to obtain a deeper depression of the hulls 12.1, 12.2, as will be explained below.
The boat 10 comprises a waterline that corresponds to the intersection of the surface of the water and the hulls 12.1 and 12.2 when the boat is stopped or sails at a reduced speed, for example at a speed of less than 8 knots for a boat 9 m in length.
Hereinafter, for a hovercraft-type boat, high speed is defined as a speed higher than the minimum hydroplaning speed of the boat, and reduced speed is defined as a speed of less than the maximum hull speed of the boat.
The boat 10 comprises a propulsion system that comprises first and second electric drives 30.1 and 30.2, placed symmetrically relative to the vertical median plane PMV, and an internal combustion engine 32 positioned on the vertical median plane PMV or symmetrically relative to the latter.
As a complement to the electric drives, the boat 10 comprises batteries for storing electrical energy.
According to a first configuration, the internal combustion engine 32 is of the outboard type and is attached to the transom 26 of the platform 14.
According to another configuration that is shown in
This internal combustion engine 32 comprises an output shaft configured to drive a propeller in rotation. According to an embodiment, the output shaft is connected to the propeller by a first linkage that comprises a vertical shaft making it possible to direct the propeller to starboard or to port, and a second linkage that comprises a horizontal shaft making it possible to immerse the propeller or to take it all the way or part of the way out of the water. According to an embodiment, the internal combustion engine 32 is of the “Z-drive” type.
As a variant, the output shaft of the internal combustion engine 32 is stationary, and the boat comprises a rudder.
The internal combustion engine 32 is not presented in more detail because it is known to one skilled in the art.
As illustrated in
Combined with the first and second drives 30.1 and 30.2, the boat 10 comprises two ducts 44 that are symmetrical relative to the vertical median plane PMV, a first duct 44 placed in the first hull 12.1 and a second duct 44 in the second hull 12.2 when the boat is a catamaran.
As illustrated in
According to a characteristic, each duct 44 has a length, starting from the transom 16.1, 16.2 of the boat, such that the side opening 54 is offset toward the aft section relative to the center of gravity of the boat. According to an embodiment, each duct 44 has a length, distance separating the side opening 54 from the transom 16.1, 16.2, of less than ¼ of the length of the boat (distance separating the bow and the stern of the boat). The length of the ducts 44 is to be the smallest possible to reduce the pressure drops and to increase the rotational torque when making sternway. By way of indication, for a boat of approximately 9 m, the side opening 54 is positioned at a small distance from the transom 16.1, 16.2, on the order of 1.3 m, less than 2 m.
The front section 52 is oriented in such a way that the stream of water exiting from the side opening 54 is directed in a direction F forming an angle of between 20 and 60° relative to the outside wall 18.1 or 18.2 and oriented toward the bow. Thus, the direction F is essentially perpendicular to the line passing approximately through the center of the side opening 54 and the center of gravity of the boat G, as illustrated in
According to a characteristic of the invention, the central section 46 has a diameter that is greater than or equal to 150 mm. The diameter of the central section 46 is proportional to the dimension of the boat. The propeller has a diameter that is very slightly smaller than that of the central section. The larger the diameter of the propeller, the higher the propulsion output. Moreover, the diameter should not be too large so that the side and rear openings are immersed during the operation of the two electric drives 30.1 and 30.2. For a 9 m boat, the propeller has a diameter that is greater than or equal to 150 mm, preferably on the order of 300 mm. This configuration makes it possible to produce a significant flow of water propelled by the propeller.
Each electric drive is preferably configured to operate in an optimal manner with a reduced rpm regime of the propeller, on the order of 1,500 rpm with ducts on the order of 300 mm in diameter and an approximately 9 m boat. This solution makes it possible to optimize the overall performance of the electric drives 30.1 and 30.2 that should operate at low pressure and high throughput.
According to another characteristic, the first and second drives 30.1 and 30.2 are configured to generate propulsion toward the bow when the propeller 42 rotates in a first direction of rotation and the water is ejected via the rear opening 50, or propulsion toward the aft section when the propeller 42 rotates in a second direction of rotation (opposite to the first direction) and the water is ejected via the main side opening 54.
To improve the performance of the propulsion system when making headway, the duct 44 comprises at least one converging nozzle in the direction of flow passing from the side opening 54 to the rear opening 50. This converging nozzle makes it possible to optimize the performance when the boat is making headway.
According to a configuration, the rear section 48 comprises a converging nozzle 56 in such a way that the rear opening 50 has a passage cross-section S50 that is smaller than the passage cross-section S46 of the central section 46. According to an embodiment, the converging nozzle 56 adjoins the rear opening 50. This position makes it possible to produce an acceleration of the stream of water at the outlet and therefore a reduction in pressure to a value that is close to the water pressure outside of the duct 44.
According to another configuration, the front section 52 comprises a converging nozzle 56′, in the direction of flow passing from the side opening 54 to the rear opening 50, in such a way that the side opening 54 has a cross-section S54 that is larger than the passage cross-section S46 of the central section 46.
According to a configuration that is shown in
According to a configuration, the side opening 54 has a cross-section S54 approximately [sic] whose surface is between 1.5 and 6 times the surface of the cross-section S50 of the outlet opening 50, ideally between 2 and 4 times the surface of the cross-section S50 of the outlet opening 50.
Along the curve L, the duct 44 does not comprise any divergent portion.
According to a characteristic of the invention, the front section 52 has a continuous curved profile in the two directions of flow (from the side opening 54 to the rear opening 50 or from the rear opening 50 to the side opening 54). As illustrated in
The side opening 54 has an approximately rectangular shape with a low height, less than 20 cm, and a great length, greater than 40 cm, as illustrated in
According to another characteristic that is shown in
According to an embodiment that is shown in
According to a second embodiment, the front section 52 comprises a main side opening 54 and at least one secondary side opening. Thus, the duct 44 comprises at least one auxiliary section that leads, at a first end, into the central section 46 and/or the front section 52 forward of the propeller 42, and, at a second end, via a secondary side opening to an inside wall 18.1, 18.2 and/or outside wall 20.1, 20.2, offset toward the aft section relative to the main side opening 54.
The front duct 52 has a larger radius of curvature than that of the auxiliary section. According to an embodiment that is shown in
According to an embodiment, the duct 44 comprises at least one inside auxiliary section 64 that leads, at a first end 65, into the central section 46 and/or the front section 52 forward of the propeller 42, and, at a second end, via an inside secondary side opening 66 to the inside wall 20.1 and 20.2, offset toward the aft section relative to the outside side secondary opening 62.
According to an embodiment, the duct comprises at least one outside auxiliary section 60 and/or at least one inside auxiliary section 64.
In the presence of secondary side openings, the main side opening has a cross-section that is smaller than the passage cross-section of the main section 46. Thus, a converging nozzle 58 is obtained when the stream of water flows from the rear opening 50 to the side openings.
The sum of the cross-sections of the side openings 54, 62, 66 is greater than the cross-section S46 of the central section 46 that is itself greater than the cross-section S50 of the rear opening 50. Thus, at least one converging nozzle is obtained when the stream of water flows from the side openings to the rear opening 50.
When the propulsion system is making headway, at a reduced speed, the water penetrates the outside and inside secondary side openings 62 and 66 via the main side opening 54, is propelled by the propeller 42 toward the aft section, and exits via the rear opening 50.
When the propulsion system is making sternway, the water penetrates via the rear opening 50, is propelled by the propeller 42 toward the bow, and exits almost exclusively via the main side opening 54. Because of the continuity of the curvature of the front section 52 and/or because the front section 52 has a larger radius of curvature than that of the outside auxiliary section(s) 60 and the inside auxiliary section(s) 64, almost no water flows into the outside auxiliary section(s) 60 and the inside auxiliary section(s) 64.
According to another characteristic, the side openings 54, 62, 66 are designed in such a way as to reduce the perturbations at high speeds.
According to an embodiment that is shown in
Tapered is defined to mean that for each hull 12.1, 12.2, the ratio between a block coefficient and a prismatic coefficient R=As/(Bwl.T) is greater than 0.7, with As being the area of the largest immersed cross-section of the hull called amidships, Bwl being the width on the waterline of the amidships, and T being the height of the amidships.
According to another special feature, the amidships is positioned in a ⅓ aft section of the length of the boat.
According to another point, on the amidships, the minimal distance between the two hulls 12.1, 12.2 on the waterline is greater than or equal to half the width of the boat.
As illustrated in
For each hull 12.1, 12.2, the body 130 comprises an almost horizontal chine 134 (in a cross-section of the boat) with a dimension of approximately 50 mm. This chine 134 is positioned at mid-bow 132, and then is offset to be positioned on the bottom 136 of each hull.
At the bow, the chine 134 is used as a deflector to channel the waves. On the aft section, as illustrated in
The bow 132 has a step 138 that projects relative to a surface that is smaller by approximately 50 mm, so as to channel the waves that go beyond the chine 134.
As illustrated in
According to a special feature, the bottom 136 of each hull forms, at the bow of the boat, a first angle α1 with the horizontal of greater than 60°, preferably on the order of 75°, which makes it possible to have inputs of spray to reduce water penetration resistance.
The bottom 136 of each hull forms, on the transom, a second angle α2 with the horizontal of less than 20°, preferably on the order of 13°. This solution makes it possible to maximize the lift.
The gap between the lines of the keel Q12 of the hulls 12.1, 12.2 gradually increases from the bow to the aft section. The keel line Q34 of the central hull 34 is always located above the line that passes through the keel lines Q12 of the hulls 12.1, 12.2 in the transverse planes. The passage cross-section of the water under the waterline at 3.5 t tends to increase from the bow to a cross-section that is located just forward of the side openings 54 and then decreases toward the stern.
According to an embodiment of the invention that is shown in
According to an embodiment, the deflector 68 comprises a projecting shape relative to the outside wall 18.1 and 18.2 at the front of the main side opening 54, as illustrated by
According to an embodiment that is shown in
According to an embodiment illustrated in
According to another embodiment, in addition to the elements mentioned above, the boat 10 could comprise a third heading and/or acceleration control 106 configured to generate a heading and/or acceleration command determined, for example, based on the position of a “joystick”-type lever.
The second control 104 can comprise a single lever, as illustrated in
The outputs of the master controller 100 are connected to one of the electric drives 30.1, to a slave controller 110 connected to another electric drive 30.2, to an actuator 112 configured to monitor the internal combustion engine 32, and to a proportional directional control valve 114 (in the case of a hydraulic cylinder) configured to monitor the position of the base of the internal combustion engine 32 that supports the propeller.
In hybrid operating mode, the master controller 100 can receive signals at these various inputs and can transmit signals via these various outputs. By way of example,
In electrical operating mode, as illustrated in
By way of example,
In electrical operating mode, the invention makes it possible—using only two electric drives 30.1 and 30.2, by modulating the rpm and the direction of rotation of the propellers 42 of the first and second drives 30.1 and 30.2 independently of one another—to move the boat forward, backward, to starboard, to port, or to rotate.
As illustrated in
As illustrated in
In electrical mode, the steering of the boat can be done in two ways:
Number | Date | Country | Kind |
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1761344 | Nov 2017 | FR | national |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2018/082905 | 11/28/2018 | WO | 00 |