1. Field of the Invention
The invention relates to the field of marine propulsion systems, and more particularly, to hydraulically powered marine outdrives.
2. Description of the Related Art
Marine propulsion systems can be classified into three broad categories: inboard, outboard, and inboard/outboard. Inboard systems typically have an inboard engine that drives a propeller on a fixed propeller shaft extending through the hull or transom with steering provided by a separate rudder. Outboard systems typically have the entire engine, drive train and propeller in a single unit mounted to the transom with steering provided by rotating the entire unit. Inboard/outboard systems typically have an inboard engine with an outboard drive system (usually a propeller) mounted to the transom, with steering provided by rotating the outboard drive. Inboard/outboard systems offer more mobility than inboard systems, and greater horsepower than purely outboard units. The term “outboard drive” is often shortened to “outdrive” and refers to the fact that the entire drive unit apart from the engine and transmission are located overboard, normally on the transom of the boat. This feature is critical to the vessel's trim, tilt and steering operations. With this type of system propulsion is achieved when rotation is transmitted from an inboard mounted engine through some form of drive train to a propeller located below the water line. Instead of a rudder setup, steering is executed by changing the angle of the entire unit in a plane parallel to the water surface. By varying this angle, propeller thrust is redirected and the vessel's course altered. The ability to direct propeller thrust makes the vessel responsive and extremely maneuverable, a feature that appeals to both commercial and pleasure boat owners.
In some known inboard/outboard systems, rotation from the inboard engine is reduced by a transmission and then directly coupled to the outdrive by a universal joint. Power is then transmitted through an arrangement of clutches, bevel gears and shafts to the propeller located below the water surface. Such fixed gear ratio arrangements tend not to use fuel to the utmost efficiency. For example, accelerating a boat from a standstill requires more horsepower than any other time during operation, and this occurs when the engine is running at low rpm and producing very little horsepower. At that time engines are over fuelled in order to create more horsepower. However most of this excess fuel that is delivered to the engine is exhausted and not used. Also, particular engines, and particularly diesel engines, have a peak performance within a narrow rpm range, so in fixed ratio systems, the engine will be operating efficiently in a limited number of boat speeds and so most often will be operating with reduced fuel efficiency, causing increased costs and pollution. As well, the universal joint which must penetrate the transom of the boat is both a weak link in the drive train, as well as a difficult area to seal.
Various designs have been proposed wherein the inboard engine is used to drive a hydraulic pump, and the hydraulic pump provides hydraulic fluid under pressure to an outboard reversible hydraulic motor which drives the propeller shaft, eliminating the need for a mechanical linkage through or over the transom. See, for example, U.S. Pat. No. 3,139,062 to Keefe, U.S. Pat. Nos. 3,587,511 and 3,847,107 to Buddrus, and U.S. Pat. No. 3,599,595 to James. In these disclosures, a hydraulic motor is mounted on the propeller shaft, below the water line. But such designs result in large drag due to the volume of the housing which is below the water line. To reduce drag requires reducing the cross-sectional profile of the housing, which necessarily reduces and limits the power output of the motor.
In U.S. Pat. No. 2,486,049 to Miller and U.S. Pat. No. 3,673,978 to Jeffrey et al. the hydraulic motor is mounted above the water line and connects to the propeller shaft through bevel gears. In U.S. Pat. No. 5,813,887 to Mark, the hydraulic motor above the water line connects to the propeller shaft by a chain drive. But all such mechanical linkages have inherent disadvantages found in vibrations and noise, limitations on turning angles, maintenance and repair, added lubrication requirements, and cost.
There is a need for a lower cost, lower maintenance, simpler, high performance hydraulic marine outdrive.
According to the invention, a hydraulic motor for a marine outdrive comprises a hydraulically driven vane motor with vanes reciprocally mounted to a rotor disposed eccentrically within a housing for rotation about an axis. The invention is characterized by the rotor being spool-shaped wherein the effective area of each vane is greater intermediate the ends of the rotor than at the ends of the rotor. The housing is preferably shaped as a truncated fusiform and the vanes have an edge complementary to the housing shape.
In one aspect, the rotor has a hollow shaft extending the length of the rotor on the axis. In another aspect, the hydraulic motor comprises a second hydraulically driven vane motor in tandem with the first vane motor, a diverter manifold fluidly connected to each vane motor, and a control valve fluidly connected to the diverter manifold for controlling the flow of hydraulic fluid to either or both vane motors.
In another aspect of the invention, a marine propulsion system comprises an inboard engine, a hydraulic pump driven by the engine, and an outdrive fluidly connected to the hydraulic pump, the outdrive having a hydraulically driven vane motor of the aforementioned construction
In the drawings:
A marine propulsion system 10 of the present invention is shown in
Looking now also at
Inside the motor 20, as shown in
Each vane 44 is preferably as long as the rotor 42 and is mounted to the rotor for reciprocal movement within a slot 52. A bias member 54 such as one or more springs 55 is mounted in the slot between the rotor 42 and a proximal edge 56 of the vane 44. A distal edge 58 of the vane has a shape complementary to the fusiform shape of the housing 26. As the rotor 42 rotates about the axis of the shaft 28 (disposed eccentrically within the housing 26), the vanes 44 reciprocate within the slots 52, with each distal edge 58 in sealing engagement with the interior wall of the housing 26. See
In a second embodiment illustrated in
It is understood that if the hydraulic fluid flow is reversed in the system, the propeller will be caused to rotate in a reverse direction wherein the vessel will be propelled rearwardly. Speed is controlled by controlling the pressure and volume of the hydraulic fluid.
While the invention has been specifically described in connection with certain specific embodiments thereof, it is to be understood that this is by way of illustration and not of limitation, and the scope of the appended claims should be construed as broadly as the prior art will permit.
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/US06/18172 | 5/11/2006 | WO | 00 | 11/16/2007 |
Number | Date | Country | |
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60594879 | May 2005 | US |