The present invention generally relates to water jet propulsion systems for watercraft and more particularly pertains to the use of a particular type of pump configuration and its adaptation to a watercraft to achieve enhanced efficiency.
A variety of jet pump configurations have previously been used to propel watercraft. Most such configurations comprise kinetic pumps of one form or another that serve to accelerate water to a high velocity in order to achieve the desired propulsive force. The losses associated with the high velocities, the non-aligned flow and the turbulent flow inherent in the operation of many such pump configurations limits the efficiency that is ultimately attainable. Nonetheless, kinetic pumps, or dynamic pumps as they may also be referred to, are the most commonly used type of pump for marine propulsion applications and typically rely on an impeller to push water through a duct. Positive displacement pumps on the other hand are capable of generating high hydrostatic pressures at essentially zero velocity and could conceivably be able to provide substantial gains in terms of efficiency. However, the positive displacement pump configurations that have been proposed for the propulsion of watercraft and the adaptations of such pumps to watercraft that have been proposed have failed to cause the use of positive displacement pumps to gain wide acceptance for such purpose.
It is well known that the velocity with which a water jet is discharged from a watercraft relative to the velocity of the watercraft has a direct effect on the efficiency of such a system. Propulsion efficiency, whether measured with respect to fuel consumption or vessel speed, is a function of both water jet discharge velocity and volumetric flow. While the water jet discharge velocity can of course be controlled by pump's volumetric output, the jet velocity can also be controlled by varying the cross-sectional area of the orifice through which the water is discharged. Accordingly an increase in the cross sectional area of the discharge orifice for a given pump output reduces the water discharge velocity while a decrease of the cross-sectional area serves to increase said velocity.
It has long been recognized that the ability to vary discharge orifice area can significantly enhance propulsion efficiency over a wide range of operating conditions and thereby reduce fuel consumption. A large variety of configurations that are either cylindrical, conical, hemispherical or combination of same have been suggested for a discharge orifice that is variable in terms of both area and flow path shape along with various mechanisms to control the water discharge velocity as a function of any of various parameters. Even greater efficiency would nonetheless be desirable.
The present invention provides a highly efficient water jet propulsion system for a watercraft by relying on a non-pulsating positive displacement pump to move water through a duct. Moreover, the pump is preferably arranged so as to be fully submerged at all times. It is further preferred to arrange its inlet opening such that water is forced directly into the pump by the movement of the watercraft through the water. It is additionally preferred to combine the pump with a submerged variable area discharge opening so as to allow for the velocity of the discharge jet to be optimized relative to the velocity of the surrounding water. Finally, it is preferred to package the entire propulsion system so as to be attachable to the bottom of a hull or other fully submerged surface of a watercraft.
A positive displacement pump displaces a preselected volume of water from the input side of the pump to the output side of the pump with each pump cycle or rotation and substantially precludes any return of water from its output side to its input side even when operating at low velocities and/or under high head pressures. Positive displacement pumps add both potential energy as well as kinetic energy to a continually displaced volume of water and the displaced volume per cycle or rotation is independent of cycle or rotation rate. As such, positive displacement pumps are readily distinguishable from kinetic or dynamic pumps that rely on for example impellers or paddle wheels to move water. A positive displacement pump is capable of generating substantial hydrostatic pressures at very low jet velocities. Non-pulsating configurations generate a constant flow throughout each cycle or rotation. This delivery characteristic has unexpectedly been found to further enhance efficiency in propelling a watercraft. The net result is an increase in performance potential, a reduction in fuel consumption and a commensurate reduction in emissions.
The preferred pump configuration is a counter-rotating rotor pump which may also be referred to as a counter-rotating lobe pump or external gear pump. Additionally it is preferred that the rotors' lobes follow a helical path along the rotors' rotational axes with a sufficient amount of twist to ensure that there is a continual discharge of fluid as the rotors are rotated. An example of such a pump is described in U.S. Pat. No. 3,164,099 to Hitosi Iyoi which is incorporated herein by reference in its entirety.
The efficiency provided by the positive displacement pump is further enhanced with its combination with a discharge opening that is continuously variable in terms of its cross-sectional area. Such discharge configuration employs an opening having a cross-sectional shape that is substantially trapezoidal. The sides of the discharge opening transverse to the parallel sides are straight or curved and may be substantially parallel so as to define a rectangle. Additionally, the discharge duct is positioned on the submerged portion of the watercraft hull so that the pump discharge flow is ejected into the surrounding water thereby creating a direct hydraulic coupling to thereby enhance thrust efficiency.
It is additionally preferred that the inlet be arranged so as to cause water to be forced into the pump as the watercraft moves through water. This inlet ram feature has the benefit of increasing the static pressure head on the suction side of the pump thereby reducing the possibility of rotor cavitation at high pump speeds and therefore allows the pump to operate at higher speeds than have heretofore been possible. Efficiency is further enhanced by arranging the inlet, pump and outlet along a straight line. This not only ensures that the entire propulsion system is fully submerged at all times to preclude any loss of prime but further eliminates any inefficiencies that could otherwise be introduced if the flow of water into, through and out of the pump were forced to change direction.
On vessels that generally have a flat bottom, the discharge opening of the duct may generally define a horizontally oriented tapered trapezoidal duct. On large vessels, several ducts may be installed at various orientations on the submerged portion of the curved hull. A contoured or generally wedge-shaped control element is movably disposed within the duct such that its narrow end is variably extendible out through the exit of the discharge opening. The control element thereby serves to block off a central portion of the discharge opening to reduce the total cross-sectional area that remains open to the flow of water there through. Its wedge shape serves to block off a progressively larger portion of the discharge opening's cross-sectional area as the control element is caused to translate out through the discharge opening which in turn results in an increase in the water jet velocity. Conversely, retraction of the control element serves to increase cross-sectional area to thereby reduce water jet velocity.
The linear position of the wedge-shaped control element may be translated by any number of actuation means including, but not limited to, mechanical, hydraulic, or servo electronic systems or combinations thereof. A variety of different control means may also be relied upon to govern the position to which the control element is actually shifted including, but not limited to, manual selection, direct action of pump output or more sophisticated systems such as for example a microprocessor that considers a plurality of parameters and calculates an optimum setting. A preferred embodiment simply relies on the action of a spring to bias the control member into its retracted position. As the force of the flow of water impinging on the frontal surfaces of the control element is increased by an increase in the volumetric pump output, the bias of the spring is overcome to cause the control element, which is constrained vertically between the upper and lower, parallel surfaces of the discharge duct, to shift linearly towards the discharge opening thereby causing a further increase in flow velocity.
The location and orientation of the discharge opening serves to further enhance the propulsion efficiency of the water jet discharge system of the present invention. Accordingly, the discharge opening is positioned so as to remain submerged at all times to create a direct hydraulic reaction between the discharge jet and the surrounding body of water. By positioning the discharge opening so as to extend from the bottom of the hull at a location substantially forward of the trailing edge of the hull, the section of hull aft of the discharge opening in the plane of the upper surface of the duct prevents the upward diffusion of the jet. Additionally, an extension of the duct's bottom surface aft of the discharge opening limits the amount of downward diffusion of the jet in the plane of the lower surface of the duct. By constraining the discharged jet between the hull and the duct extension aft of the discharge opening, a greater portion of the discharge flow is constrained so as to remain substantially parallel to the direction of desired thrust i.e. in-line with the direction of travel. The result is an increase in axial thrust, or vessel driving force, than if the pump discharge is allowed to diffuse freely.
The pump, inlet opening and discharge opening are preferably disposed within a housing that is attachable to the bottom of the hull of a watercraft. A transfer box extending upwardly and through the hull is relied upon to transfer rotation from a prime mover to the pump. It is important that the shape of the submerged portion of the pump housing is streamlined in such a way so as to minimize the hydrodynamic impact of its presence in such a critical location.
These and other advantages of the present invention will become apparent from the following detailed description of preferred embodiments which, taken in conjunction with drawings, illustrate by way of example the principles of the invention.
a is a perspective view of the helical rotors shown in
The water jet propulsion system of the present invention provides for enhanced efficiency in the propulsion of a watercraft. The figures generally illustrate preferred embodiments of the propulsion system in terms of its pump configuration, its adaptation to and orientation relative to a hull, a mechanism for varying the cross-sectional area of the discharge opening and the packaging of its various components.
While the embodiment illustrated in
In operation, reliance on a non-pulsating positive displacement pump in water jet propulsion systems yields substantial gains in efficiency over previously used devices. More specifically, a counter-rotating helical rotor pump is able to provide an aligned continuous flow at the most efficient velocity without turbulence. The non-pulsating flow characteristic eliminates the thrust disruptions inherent in pulsating configurations and the inefficiencies resulting therefrom. Such pump in conjunction with a fully submerged discharge opening having a variable cross-sectional area yields extremely high propulsion efficiency over the entire range of pumping capacity. Adjustment of the cross-sectional area of the discharge opening allows the discharge jet velocity to be set to propel a vessel at its best fuel efficiency or, if desired, to provide maximum driving force over a wide range of vessel operating parameters such as weight, displacement and weather conditions. The submerged variable area discharge opening in combination with the installation location on the hull and a bottom lip serve to limit diffusion of the water jet thereby minimizing the dynamic mixing losses aft of the discharge plane allowing the hydraulic reaction to be maximized. It is contemplated that the propulsion system of the present invention can be sized and adapted to most any watercraft from motorized surfboards and kayaks, to sport and pleasure boats to freighters and tankers. In each such application, overall energy consumption can be significantly reduced as the water discharge velocity leaving the housing can be optimized at any given vessel speed to yield the highest possible propulsion efficiency using the least amount of fuel. Unlike water jet propulsion systems that discharge above the waterline of a vessel, there is no need for complicated diversion systems that direct the flow of water forward to provide reverse thrust. A simple reversing of the rotor rotation provides reverse thrust by causing the water to flow from the submerged discharge end out the submerged inlet.
While particular forms of the invention have been described and illustrated, it will also be apparent to those skilled in the art that various modifications can be made without departing from the spirit and scope of the invention. Accordingly, it is not intended that the invention be limited except by the appended claims.
This application is a continuation-in-part of U.S. Ser. No. 11/771,035, filed on Jun. 29, 2007, which is a divisional of U.S. Ser. No. 11/103,318 filed on Apr. 11, 2005, now U.S. Pat. No. 7,238,067.
Number | Date | Country | |
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Parent | 11103318 | Apr 2005 | US |
Child | 11771035 | US |
Number | Date | Country | |
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Parent | 11771035 | Jun 2007 | US |
Child | 12247177 | US |