The present application claims priority under 35 U.S.C. §119 to Japanese Patent Application No. 2013-226878, filed on Oct. 31, 2013. The entire disclosure of Japanese Patent Application No. 2013-226878 is hereby incorporated herein by reference.
1. Field of the Invention
The present invention relates to a jet propelled watercraft.
2. Description of the Related Art
To stabilize behavior of a vessel body when reducing the speed of a jet propelled watercraft, a method has been disclosed that, when the forward speed of the vessel is greater than a predetermined speed, thrust to reduce the speed of the vessel body is further reduced in comparison with when the forward speed of the vessel body is less than or equal to the predetermined speed (see U.S. Pat. No. 8,177,594).
However, according to the method described in U.S. Pat. No. 8,177,594, thrust is set in accordance with the forward speed at the start of reducing the speed. Hence, it is difficult to simultaneously implement a prompt speed reduction and a stabilized behavior of the vessel body. Specifically, where the predetermined speed is set to be somewhat high, the behavior of the vessel body is likely to be unstable when the forward speed is slightly less than the predetermined speed. This is because, in such a condition, the behavior of the vessel body easily becomes unstable, although the thrust is large.
By contrast, where the predetermined speed is set to be somewhat low, a prompt speed reduction cannot be implemented when the forward speed is slightly greater than the predetermined speed. This is because, in such a condition, the behavior of the vessel body is unlikely to be unstable, but thrust is small.
Preferred embodiments of the present invention have been conceived in view of the aforementioned situation. A preferred embodiment of the present invention provides a jet propelled watercraft that achieves both a prompt speed reduction and a stabilized behavior of a vessel body during the speed reduction.
A jet propelled watercraft according to a preferred embodiment of the present invention includes a vessel body, a jet propulsion mechanism, a controller, and a bucket. The jet propulsion mechanism is configured to propel the vessel body. The controller is configured and programmed to control a thrust of the jet propulsion mechanism to propel the vessel body. The bucket is configured to move to a retracted position spaced away from the jet of water ejected from the jet propulsion mechanism and a jet receiving position to receive the jet of water ejected from the jet propulsion mechanism. The controller is configured and programmed to change an increase rate of the thrust in accordance with a forward speed of the vessel body until the thrust is increased to a predetermined value after the bucket has been moved from the retracted position to the jet receiving position.
According to preferred embodiments of the jet propelled watercraft described below, a jet propelled watercraft is provided that achieves both a prompt speed reduction and a stabilized behavior of a vessel body during the speed reduction.
The above and other elements, features, steps, characteristics and advantages of the present invention will become more apparent from the following detailed description of the preferred embodiments with reference to the attached drawings.
With reference to the drawings, explanation will be hereinafter made for a schematic structure of a jet propelled watercraft 1 according to preferred embodiments of the present invention.
The jet propelled watercraft 1 preferably is so-called a personal watercraft (PWC), for example. The jet propelled watercraft 1 includes a vessel body 2, an engine 3, a fuel tank 4, a jet propulsion mechanism 5, a bucket 6, the seat 7, a steering handle 8, a speed sensor 9, and a controller 10.
The vessel body 2 includes a deck 2a and a hull 2b. An engine compartment 2c is provided inside the vessel body 2. The engine compartment 2c accommodates the engine 3, the fuel tank 4 and so forth. The engine 3 includes a crankshaft 31 extending in the back-and-forth direction.
The jet propulsion mechanism 5 is configured to generate thrust to propel the vessel body 2 by a driving force from the engine 3. The jet propulsion mechanism 5 is configured to suck in and eject water that surrounds the vessel body 2. The jet propulsion mechanism 5 includes an impeller shaft 50, an impeller 51, an impeller housing 52, a jet nozzle 53, and a steering nozzle 54.
The impeller shaft 50 is disposed so as to extend rearward from the engine compartment 2c. The front portion of the impeller shaft 50 is coupled to the crankshaft 31 through a coupling member 36. The rear portion of the impeller shaft 50 extends into the impeller housing 52 through a water suction member 2e of the vessel body 2. The impeller housing 52 is connected to the rear portion of the water suction member 2e.
The impeller 51 is attached to the rear portion of the impeller shaft 50. The impeller 51 is disposed inside the impeller housing 52. The impeller 51 is configured to be rotated together with the impeller shaft 50 and suck water into the impeller housing 52 through the water suction member 2e. The impeller 51 is configured to rearwardly eject the sucked in water out of the jet nozzle 53. The jet nozzle 53 is disposed rearward of the impeller housing 52. A support bracket 53a to support the bucket 6 is fixed to the jet nozzle 53.
The steering nozzle 54 is disposed rearward of the jet nozzle 53. The steering nozzle 54 includes a jet port 54a. A jet of water that propels the vessel body 2 is ejected from the jet port 54a rearward. The steering nozzle 54 is mounted so as to be pivotable right and left. The steering nozzle 54 is configured to switch the ejection direction of the jet of water between right and left in response to the operation of the steering handle 8. The steering nozzle 54 is preferably configured to switch the ejection direction between up and down in response to the operation of a trim adjustor switch mounted to the steering handle 8.
The bucket 6 is disposed rearward of the jet propulsion mechanism 5. The bucket 6 is supported by the support bracket 53a, while being pivotable up and down about a pivot shaft 6a extending right and left. The bucket 6 is configured to move to a position spaced away from the jet of water ejected from the jet port 54a (hereinafter referred to as “a retracted position”) and a position to receive the jet of water ejected from the jet port 54a (hereinafter referred to as “a jet receiving position”). In the present preferred embodiment, the jet receiving position is a concept that includes: a position in which thrust does not act on the vessel body 2 (hereinafter referred to as “a neutral position”, see
The seat 7 is attached to the deck 2a. The seat 7 is disposed over the engine 3. The steering handle 8 is disposed forward of the seat 7. The steering handle 8 is an operating member configured to steer the vessel body 2. The steering handle 8 is equipped with a throttle operating member 8a and a shift operating member 8b.
The throttle operating member 8a is an operating member configured to regulate the throttle opening degree of the engine 3. A vessel operator regulates the thrust of the jet propulsion mechanism 5 by changing the operating amount of the throttle operating member 8a.
The shift operating member 8b is movable to a forward shift position, a rearward shift position, and a neutral shift position. When the shift operating member 8b is switched into the forward shift position, the bucket 6 is configured to be moved to the retracted position. When the shift operating member 8b is switched into either the neutral shift position or the rearward shift position, the bucket 6 is configured to be moved to the jet receiving position (the neutral position or the rearward thrust position).
The speed sensor 9 is attached to the hull 2b and disposed under the jet nozzle 53. In the present preferred embodiment, a paddle turbine is used as the speed sensor 9. It should be noted that for the speed sensor 9, it is possible to use a rotation speed sensor configured to measure the rotation speed of the crankshaft 31 of the engine 3, a receiver configured to receive a navigation signal from a navigation satellite of GNSS (Global Navigation Satellite System) or so forth.
The controller 10 includes a computer including a CPU, a memory and so forth. The controller 10 is configured and programmed to control the thrust of the jet propulsion mechanism 5 to propel the vessel body 2.
As shown in
The target throttle opening degree determining unit 101 is configured to detect the operating amount V of the throttle operating member 8a shown in
The target throttle opening degree determining unit 101 is configured and programmed to determine the target throttle opening degree TG shown in
The target throttle opening degree determining unit 101 is configured and programmed to output the determined target throttle opening degree TG to the throttle opening degree regulating unit 103.
The regulation coefficient determining unit 102 is configured and programmed to detect the forward speed S shown in
The regulation coefficient determining unit 102 is configured and programmed to output the determined regulation coefficient R to the throttle opening degree regulating unit 103.
The throttle opening degree regulating unit 103 is configured and programmed to calculate the throttle opening degree TH shown in
The throttle opening degree regulating unit 103 is configured and programmed to control the driving force of the engine 3 by outputting the calculated throttle opening degree TH to the engine 3. As a result, the rotation speed of the impeller 51 is regulated, and as shown in
Thus, the controller 10 is configured and programmed to change the increase rate of the thrust P in accordance with the forward speed S until the thrust P is increased to the second thrust P2 (an exemplary predetermined value) after the bucket 6 has been moved from the retracted position to the jet receiving position (i.e., in a period from the clock time T5 to the clock time T7). Thus, the speed of the vessel body 2 is reduced with the necessary and sufficient thrust P in a period from the clock time T5 to the clock time T7. Hence, the vessel body 2 is promptly reduced in its speed while being stabilized in its behavior.
The exemplary preferred embodiments of the present invention have been described above. However, the present invention is not limited to the aforementioned exemplary preferred embodiments, and a variety of changes can be herein made without departing from the scope of the present invention.
In the aforementioned exemplary preferred embodiments, the controller 10 is preferably configured and programmed to gradually increase the increase rate of the thrust P by gradually increasing the regulation coefficient R in accordance with a reduction in the forward speed S until the thrust P is increased to the second thrust P2. However, until the thrust P is increased to the second thrust P2, the controller 10 may be configured and programmed to gradually reduce the increase rate of the thrust P in accordance with the reduction in the forward speed S, or alternatively, may be configured and programmed to keep the increase rate constant.
In the aforementioned exemplary preferred embodiments, the controller 10 is preferably configured and programmed to determine the regulation coefficient R in accordance with the chart shown in
While preferred embodiments of the present invention have been described above, it is to be understood that variations and modifications will be apparent to those skilled in the art without departing from the scope and spirit of the present invention. The scope of the present invention, therefore, is to be determined solely by the following claims.
Number | Date | Country | Kind |
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2013-226878 | Oct 2013 | JP | national |