The present disclosure relates to marine propulsion systems and, more specifically, to a “final drive” arrangement having counter-rotating impellers, that can be coupled to many types of existing propulsion arrangements, including outboards, sterndrives, pod drives, inboards and/or the like.
Existing marine propulsion systems typically utilize propellers (e.g., in the case of outboards, inboards, sterndrives, and pod drives) or impellers (e.g., in the case of jet drives) which rotate in a direction generally perpendicular to the surface of the water (or keel of the vessel). In other words, the rotation axes of known propellers or impellers extend along a direction generally parallel to the surface of the water. These systems may have certain drawbacks, including high drag levels due to excessive equipment surface below the waterline, high levels of cavitation due to the inefficiency of the direction of rotation in comparison to the direction of water flow, safety related issues due to rotating blades exposed in open water, and/or the like.
Many conventional marine propulsion systems also include a direct connection between the engine or motor and the drive unit, thereby locking the propeller speed directly in relation to the input speed. This reduces the efficiency of the system under certain conditions.
The present disclosure provides a marine vessel having a hull with a pair of opposite sides disposed at an angle with respect to one another, the opposite sides also disposed at an angle with respect to a water surface. A marine propulsion system is operatively coupled to the hull and includes a pair of impellers associated respectively with the pair of hull sides that rotate within respective impeller planes disposed generally parallel to the hull sides to convey water from at least one inlet though at least one outlet to provide thrust to the vessel. The marine propulsion system may also be contained within an outboard unit mounted to a transom of the vessel.
Embodiments of the present disclosure include a marine propulsion system that is adaptable to many existing powerplant designs, facilitates increased safety as a result of no exposed moving blades, facilitates improved propulsion efficiency through lower case drag and improved water flow arrangement through the propulsor, facilitates the ability to change the ratio of input speed to impeller speed, and facilitates improved vessel control as a result of control surfaces and outlet nozzle configurations.
Embodiments include a marine propulsion system having an input shaft attached directly to an outboard, sterndrive, pod drive or inboard/transfer case output shaft. In embodiments, the propulsion system is configured to replace the lower unit, or drive case, on existing outboards, sterndrives, and pod drives, and may be directly mounted to an inboard vessel when driven by a 90 degree drive case connected to the inboard engine/transmission. The input shaft may be directly connected to an idler or drive gear, which is used to drive a first impeller gear. The first impeller gear drives a second impeller gear, thereby connecting the impellers in a counter-rotation configuration. The input gears may be designed such that the impeller rotation of the impellers draws water through the impellers and towards the aft (rear) portion of the vessel and into an output nozzle. In embodiments, the input shaft may be directly connected to a transmission device, such as a hydro-mechanical transmission or a constant velocity transmission, which is connected to one of the impeller gears.
Because the impellers may be constantly in motion as long as the engine or motor are operating, water pressure is available near the impeller output area which can be utilized to cool the engine in the case of an internal combustion engine. This may eliminate a need for external water pumps which may be prone to premature wear and failure. Additionally, the impellers may be arranged in parallel with the water surface, thereby mitigating drag on the propulsion system housing. The housing may be designed such that it provides lift to the vessel as well as control surfaces which assist in steering and boat trim.
A marine propulsion system includes two counter-rotating impellers arranged in a fashion generally parallel to the surface of the water and driven by two counter-rotating drive gears which are attached to a drive shaft through means of either a drive gear directly attached to the input drive shaft from the engine or through a transmission device which may change the drive ratio between the engine and the propulsion system gears. A housing designed to envelop the impellers, may provide water ingress and egress paths, including inlet ports which prevent accidental access to the impeller region, and a movable output nozzle on the outlet of the housing which provides steering control, trim control, and thrust reversal. The housing may also provide a path for exhaust gas flow from an engine under the water level, provide a water flow path for cooling water that is transferred from the impellers to the engine, and/or provide a hydro-dynamic surface and control surface to assist with the control of the vessel. In embodiments, the propulsion system is highly adaptable and may be utilized in conjunction with outboard, sterndrive, and/or pod drive propulsion arrangements, or may be integrated directly into the hull of the vessel and driven similar to an inboard propulsion arrangement, e.g., by using a 90 degree drive gear housing inside the vessel.
In one form thereof, the present disclosure provides a marine vessel, including a hull having a pair of opposite sides disposed at an angle with respect to one another and with respect to a water surface; and a marine propulsion system operatively coupled to the hull and including a pair of impellers respectively associated with the pair of hull sides that rotate within respective impeller planes disposed generally parallel to the hull sides to convey water from at least one inlet through at least one outlet to provide thrust to the vessel; and at least one drive source drivingly coupled to the impellers.
In another form thereof, the present disclosure provides a marine vessel, including a hull having a transom and a pair of sides disposed at an angle with respect to one another and with respect to a water surface; and at least one outboard unit attached to the transom and including a marine propulsion system including at least one drive source; a housing including at least one inlet and at least one outlet; and an impeller disposed within the housing that rotates within an impeller plane disposed generally parallel to one of the sides of the hull and at an angle with respect to a water surface to convey water from the inlet though the outlet to provide thrust to the vessel.
While the present disclosure is amenable to various modifications and alternative forms, specific embodiments have been shown by way of example in the drawings and are described in detail below. The present disclosure, however, is not limited to the particular embodiments described. On the contrary, the present disclosure is intended to cover all modifications, equivalents, and alternatives falling within the ambit of the present disclosure as defined by the appended claims.
As shown in
According to embodiments, the marine propulsion system 102 includes two counter-rotating impellers arranged in a fashion generally parallel to the surface of the water. In other words, the rotation axes of the impellers extend in directions substantially perpendicular to the surface of the water. The propulsion system 102 may be configured to be highly adaptable and may be utilized in conjunction with outboard, sterndrive, and/or pod drive propulsion arrangements and/or may be integrated directly into the hull 104 of the vessel 100 and driven similar to an inboard propulsion arrangement, for example, by using a 90 degree drive gear housing inside the vessel 100. The housing 110, which may be designed to surround or envelop the impellers, provides water ingress and egress paths. The output nozzle 112 may be moveable, thereby facilitating both steering and trim control. Additionally, the output nozzle 112 may provide a path for exhaust gas flow from an engine under the water level, provide a water flow path for cooling water that is transferred from the impellers to the engine, and/or provide a hydro-dynamic surface and control surfaces to assist the planning and control of the vessel.
The housing 202 may enclose a chamber 205, and generally includes an upper surface 208, a generally parallel and opposite-facing lower surface 210, a front portion 212, and the rear portion 206. The upper surface 208 may include attachment features (not shown) for coupling the housing 202 to a hull of a vessel, and such, attachment features may be included on other portions of the housing 202 such as, for example, for coupling the housing 202 within a portion of a hull. Control surfaces may be disposed on the outside of other portions of the housing 202. In embodiments, for example, one or more winglets may be disposed on each side of the housing 202 at the front portion 212 and/or the rear portion 206. These control surfaces may facilitate improved steering under off-throttle conditions.
As shown in
In embodiments, the housing 202 may include two input ports 232 such that a first input port 232 is arranged to provide water input to a first impeller 222 and a second input port 232 is arranged to provide water input to a second impeller 226. Any number of desired input ports may be disposed within the housing at any number of different positions. Additionally, the input port 232 may be configured according to any number of different shapes and may, in embodiments, be configured so as to increase the flow of water, decrease the flow of water, focus the flow of water, and/or the like. In embodiments, the input port 232 may include an adjustable feature configured to enable a user and/or control system to adjust the profile of the input port 232.
Each of the impellers 222 and 226 may include a number of blades 238 configured such that as the impeller rotates, water is moved from the input port 232 toward the output nozzle 204, e.g., along an illustrative flow path generally indicated at 240, shown in
For example, the marine propulsion system 300 may be, or include, the marine propulsion system 102 depicted in
The housing 316 may enclose a chamber 320, and generally includes an upper surface 322, a generally parallel and opposite-facing lower surface 324, the front portion 312, and the rear portion 314. The upper surface 322 may include attachment features (not shown) for coupling the housing 316 to a hull of a vessel. In embodiments, attachment features may be included on other portions of the housing 316 such as, for example, for coupling the housing 316 within a portion of a hull. As shown in
In this manner, the first impeller 302 may be configured to rotate in a clockwise direction 340, which causes the second impeller 304 to rotate in a counterclockwise direction 342. The counter-rotating impellers 302 and 304 pull water in through the input port 306 disposed on the front portion 312 of the housing 316 and push water out of the nozzle 318, through an opening 344 disposed therein. A grate 346 (or other protective covering such as, for example, a screen) may be disposed over the input port 306 to prevent objects from entering the chamber 320 and causing damage to, and/or being damaged by, the impellers 302 and 304 and/or other parts within the housing 316.
Each of the impellers 302 and 304 may include a number of blades 308 configured such that as the impeller rotates, water is moved from the input port 306 toward the output nozzle 318, e.g., along the illustrative flow path generally indicated at 310. In embodiments, the impellers 302 and 304 (and blades 308) may be configured according to any number of impeller designs, including designs that are generally similar to the design of Pelton wheels, as shown in
The impellers of each pair may be rotated at the same speed or at different speeds. In one embodiment, the first impeller 402, 406 of each pair may be driven at a greater speed than the second impeller 404, 408 of each pair. In this manner, the input drive to the first impellers 402, 406 may be different, or separated from, the input drive to the second impellers 404, 408, or a common input drive may be used which is geared in a different manner between the first and second impeller sets to drive same at different speeds.
For example, the marine propulsion system 400 may be, or include, the marine propulsion system 102 depicted in
The housing 424 may enclose a chamber 428, and generally includes an upper surface 430, a generally parallel and opposite-facing lower surface 432, the front portion 422, and the rear portion 418. The upper surface 430 may include attachment features (not shown) for coupling the housing 424 to a hull of a vessel, and attachment features may be included on other portions of the housing 424 such as, for example, for coupling the housing 424 within a portion of a hull. As shown in
As illustrated, the CVT 448 may include a drive pulley 450, coupled to the drive shaft 436, and a driven pulley 452 that engages the drive gear 438, with a v-belt 454 extending between the pulleys 450 and 452. The gear ratio may be changed, as with conventional CVT systems, by adjusting the effective diameters of the pulleys 452 and 454. That is, for example, as shown in
In this manner, the first and second impellers 402 and 404 may be configured to rotate in a clockwise direction 464, which causes the third and fourth impellers 406 and 408 to rotate in a counterclockwise direction 466. The counter-rotating impellers 402, 404 and 406, 408 pull water in through the input ports 410 and 412 disposed on the front portion 422 and bottom portion 416 of the housing 424, respectively, and push water out of the nozzle 426, through an opening 468 disposed therein. A grate 470 (or other protective covering such as, for example, a screen) may be disposed over the input port 410 to prevent objects from entering the chamber 428 and causing damage to, and/or being damaged by, the impellers 402, 404, 406, and 408 and/or other parts within the housing 428. Similarly, a grate 472 (or other protective covering such as, for example, a screen) may be disposed over the input port 412.
Each of the impellers 402 and 406 may include a number of blades 414 configured such that as the impeller rotates, water is moved from the input port 410 toward the output nozzle 426, e.g., along the illustrative first flow path generally indicated at 474, which is substantially parallel to the surface of the water. In embodiments, the impellers 402 and 406 (and blades 414) may be configured according to any number of impeller designs, including designs that are generally similar to the design of Pelton wheels, as shown in
In
Referring to
The marine propulsion system generally includes a drive source 512, such as an engine or motor which, in this embodiment, is carried within or above hull 502. An exemplary drivetrain between drive source 512 and the propulsion system includes an output shaft 514 drivingly coupled to drive source 512, transmission 516, and input shaft 518 drivingly coupled to the propulsion system. Transmission 516 drivingly couples input and output shafts may be a right angle drive, a geared drive or, as discussed above, a continuous variable transmission (CVT), for example. As shown in
The propulsion system also includes an impeller housing 520 mounted to, or integrated within, a lower portion of hull 502 near keel 504. Housing 520 includes a pair of counter-rotating impellers 522, which may also include associated impeller gears and drivetrain as described above in connection with prior embodiments.
However, as best shown in
As with prior embodiments, impellers 522 may include impeller gears 524 in driving engagement with one another, with input shaft 518 in driving engagement with one or both of impeller gears 524, typically through a bevel gear drive 526, for example, though other drive arrangements are possible.
Impeller housing 520 includes one or more inlets 528 (
Also similar to the prior embodiments, each impeller 522 may include a plurality of curved blades 532 as is typical with Pelton wheel or centrifugal impeller designs, and the number of curved blades may be as few as 2, 3, or 4, or as great as 6, 8, 10, or greater, for example. Each blade 532 may be curved either only in a single plane or may have a complex curvatures in multiple planes. In use, as shown in
Advantageously, with impellers 522 disposed, and rotatable within, impeller planes IP which are substantially parallel to their respective sides 510 of hull 502, the profile of housing 520 may be reduced in a manner in which housing 520 substantially conforms to the shape of hull 502 to facilitate minimum frictional drag of housing 520 in the water when vessel 500 is propelled. Housing 520 and its inlet(s) 528 and outlet(s) 520 may also be integrated into hull 502 in a manner in which the overall shape of hull 502 is substantially smooth and uninterrupted.
Referring to
Further, in connection with the above embodiments, vessel 500 may have multiple propulsion systems associated with hull 502, including multiple impellers 522 disposed in spaced relation along sides 510 of hull 502 from the bow to the stern of vessel 500 and/or multiple impellers 522 spaced between keel 504 and the upper ends of sides 510, each impeller 522 having a common drive source 512 or the impellers 522 having individual, dedicated drive sources 512.
In
As best shown in
In an additional feature of this embodiment best shown in
In
While embodiments of the present disclosure are described with specificity, the description itself is not intended to limit the scope of this patent. Thus, the inventors have contemplated that the claimed disclosure might also be embodied in other ways, to include different steps or features, or combinations of steps or features similar to the ones described in this document, in conjunction with other technologies.
This application is a continuation-in-part of U.S. patent application Ser. No. 14/861,011, entitled PROPULSION SYSTEM HAVING COUNTER-ROTATING IMPELLERS, filed on Sep. 22, 2015, which claims priority to U.S. Provisional Patent Application Ser. No. 62/053,854, entitled PROPULSION SYSTEM HAVING COUNTER-ROTATING IMPELLERS, filed on Sep. 23, 2014, and the entire disclosures of each are hereby expressly incorporated herein by reference.
Number | Name | Date | Kind |
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3017848 | Bishop | Jan 1962 | A |
3276415 | Nikolaus | Oct 1966 | A |
4538996 | Inwood | Sep 1985 | A |
4738584 | Price | Apr 1988 | A |
5203728 | Kobayashi | Apr 1993 | A |
5711657 | Hoffmeier | Jan 1998 | A |
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Number | Date | Country | |
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20170190403 A1 | Jul 2017 | US |
Number | Date | Country | |
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62053854 | Sep 2014 | US |
Number | Date | Country | |
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Parent | 14861011 | Sep 2015 | US |
Child | 15467030 | US |