1. Field of the Invention
This invention relates generally to a watercraft propelled by a water jet, and in particular, to an internal combustion engine for driving the propulsion system of such a watercraft.
2. Description of the Prior Art
A jet-boat is a boat propelled by a jet of water ejected from the back of the craft. Unlike a powerboat or motorboat that uses a propeller in the water behind the boat, a jet-boat draws the water from under the boat into a pump-jet inside the boat, then expels the injected water through a nozzle at the stern.
Jet-boats are steered and maneuvered by directing the nozzle and water jet laterally from the axis of longitudinal direction, whereby the jet both propels and steers the craft. Jet boats can be reversed and brought to a stop within a short distance from full speed using the jet.
A conventional screw impeller accelerates a large volume of water by a small amount, similar to the way an airplane's propeller accelerates a large volume of air by a small amount. In a jet-boat, pumping a small volume of water, accelerating it by a large amount, and expelling the water above the water line delivers thrust that propels the craft. Acceleration of the water is achieved by the impeller driven by a small ICE onboard the craft.
The engine includes a crank shaft, a first chamber for containing engine oil and, a second chamber for containing engine oil, a gear secured to the crankshaft, and a mating gear secured to an output shaft connected to the water impeller though a coupling. A dam, located in the second chamber, limits oil flow across the dam into the oil contained in the second chamber,
The oil flows from the first chamber to the second chamber through an orifice, providing lubrication to the gear set in the second chamber. The rotating gear brings the oil in the lower portion of second chamber into the higher position behind the dam. The orifice limits the amount of oil flow from the first chamber to the second chamber. As the gear rotates, it carries the oil from the lower portion of second chamber to the higher portion of the second chamber behind the dam so that the gear is not submerged in oil.
The dam prevents oil from flowing back from the higher portion to the lower portion in the second chamber. Another orifice permits engine oil, located behind the dam, to flow back to the first chamber. The dam and orifice operate to keep the gear lubricated without being submerged in oil, and maintain an optimum height of the oil level for lubricating the gear properly. Lubrication protection is not at its best when gears are submerged in oil.
The correct level of oil in second chamber, provided by the orifices and dam, also limits energy losses due to hydraulic drag on the gear as it rotates in the oil compared to the drag loss that would otherwise occur if the oil level were high in the second chamber. Hydraulic drag on the gear increases the magnitude of external load on the engine, potentially reduces the operating efficiency of the engine.
The system also provides a continuous supply of lubricant to the pinion, bear, shafts and bearings. As the gear rotates, oil in the second chamber is thrown radial outward in a mist onto the surfaces of the pinion and gear. An orifice, formed through wall 56, is sized to permit engine oil to flow at an acceptable rate from the first chamber into the second chamber 76, thereby replenishing oil that has been carried away as the pinion rotates through the oil in the second chamber.
The scope of applicability of the preferred embodiment will become apparent from the following detailed description, claims and drawings. It should be understood, that the description and specific examples, although indicating preferred embodiments of the invention, are given by way of illustration only. Various changes and modifications to the described embodiments and examples will become apparent to those skilled in the art.
The invention will be more readily understood by reference to the following description, taken with the accompanying drawings, in which:
Referring now to
A seat back 22, secured to the upper surface of the hull 12 supports the seated rider. The core-reinforced portion of the hull 12 is closed by a partition or bulkhead 24, located at the forward end of an engine compartment 26, which contains an engine 28, water intake duct 30, bladed impeller 32 that forces water from the intake duct, and a nozzle 34, whose angular position about a vertical axis can be varied leftward and rightward to steer the kayak 10. Water inducted through duct 30 flows through the impeller and exits through the nozzle 34. The engine compartment 26 is covered with a cowling 36 formed with an air inlet passageway 38. Cowling 36 is secured by latches to the upper surface of the hull, thereby sealing the engine compartment against entry of water when the cowling is latched to the hull. Preferably, engine 28 has a single cylinder and piston, low displacement and operates at high efficiency on a four stroke cycle.
The intake duct 30, which may be a component separate from the hull 12 or formed integrally with the hull, is of molded plastic having an intake opening 44 in the bottom of the hull, through which water is inducted and flows toward the outlet of nozzle 34. A driveshaft 46, secured to the crankshaft of engine 28 drives the bladed impeller 32 in rotation, thereby drawing water into the intake duct 30 and forcing it through the impeller and out the nozzle 34. A water jet, which propels and steers the kayak 10, rises from the outlet of nozzle 34 into the air above the water surface.
The rider pivots the joystick 16 leftward and rightward about an axis to steer the craft 10. The joystick 16 carries a button, which is depressed to start engine 28, a button that stops the engine, and an engine throttle in the form of a trigger 64 located on the underside of the joystick, by which the engine throttle is opened and closed to control engine speed and speed of the kayak 10.
The rider also pivots the joystick 16 upward and downward about axis 49 to locate its hand grip in a comfortable position during use and in a downward position when the craft 10 is stored or being transported. As the joystick 16 pivots, cables supported on pulleys transmit movement of the joystick to the nozzle 34, thereby steering and maneuvering the kayak leftward and rightward by redirecting the water jet exiting the nozzle relative to the longitudinal axis of the craft.
The output shaft 52 of engine 28 is supported by anti-friction bearings 54, 55 on a wall 56 formed in the engine casing 58. Shaft 52 is secured to driveshaft 46 of the water intake and discharge system. Output shaft 52 is secured to an output gear 60, which is in continuous meshing engagement with a pinion gear 62, supported on the engine crankshaft 66. Bearing 68, fitted in the wall 56 of the engine casing 58, and bearing 69 support crankshaft 66.
Engine casing 58 is formed with a first oil chamber 70, which normally contains engine lubricating oil at about level 72. A dipstick 74, threaded into an exterior wall of casing 58, can be removed to visually check the level of oil in the first oil chamber 70. Wall 56 separates the first chamber 70 from a second oil chamber 76 having a lower surface 77 that supports engine oil contained in the second chamber. Normally the upper surface of the engine oil in chamber 76 is at level 78. Gear 60 and pinion 62 are located in chamber 76, and the teeth of gear 60 rotate through the oil in chamber 76 as gear 60 is driven by pinion 62 in rotation about axis 77.
As gear 60 rotates, oil in chamber 76 is thrown radial outward in a fine mist against the inside of cover 80, onto the surfaces of pinion 62 and gear 60, and against wall 56. An orifice 100, formed through wall 56, is sized to permit engine oil to flow at an acceptable rate from chamber 70 into chamber 76, thereby replenishing oil in chamber 76 that has been carried away as pinion 60 rotates through the oil in chamber 76.
A partition or dam 102, formed in supported on hat wall 56, is located in second chamber 76 on a second surface 103 that is located above the surface 78 of oil contained in chamber 76. Dam 102 limits oil, which may collect in a space 104 behind the dam and at the outboard side of wall 56, from flowing from surface 103 into the oil contained in chamber 76 and located above surface 77. Instead, a second orifice 104 formed through wall 56 permits engine oil in space 104 to flow through wall 56 into chamber 70. Dam 102 and orifice 104 operate to limit the height of the oil level 78 contained in chamber 76, thereby providing the best lubrication protection. Lubrication protection is not at its best when gears are submerged in oil. Hydraulic drag on gear 60 increases the magnitude of external load on engine 28 and potentially reduces the operating efficiency of the engine.
A window 106 formed in wall 56 provides a passageway to circulate any oil mist between chambers 70 and 76.
The water flowing in annular passage 126 cools the inner pipe 122 and provides a low temperature water jacket around the inner exhaust gas pipe 124. The exhaust pipe 50 is directed upward from outlet port 120 above the waterline 132, and then downward below the waterline down. This upward and downward path blocks water from entering the engine exhaust port 120 and cylinder head.
In accordance with the provisions of the patent statutes, the preferred embodiment has been described. However, it should be noted that the alternate embodiments can be practiced otherwise than as specifically illustrated and described.