This application claims the benefit of Japanese Patent Application No. 2022-94002, filed on Jun. 9, 2022, which is hereby incorporated by reference herein in its entirety.
The present invention relates to a small marine vessel including an outboard motor that can change an action position of a thrust force.
A relatively small marine vessel such as a planing boat includes an outboard motor as a propulsion device. The outboard motor is attached to a stern of a hull so as to rotate about a tilt axis extending along a left-right direction of the hull. The outboard motor rotates (tilts up) such that an upper portion of the outboard motor moves forward and downward and a lower portion of the outboard motor moves rearward and upward about the tilt axis, or rotates (trims in) such that the upper portion moves rearward and downward and the lower portion moves forward and upward about the tilt axis (see, for example, Japanese Patent Application Laid-Open No. H01-317893).
In such a marine vessel, an action angle of a thrust force generated by a propeller of the outboard motor is changed by the tilting up or trimming in the outboard motor. For example, to maintain planing, the action angle of the thrust force is changed such that a bow is lowered by trimming in the outboard motor. In this manner, a posture of the hull can be controlled by the outboard motor being tilted up or trimmed in.
However, an action position of the thrust force does not change in the left-right direction of the hull even if the outboard motor is tilted up or trimmed in, and thus, the tilting-up or trimming-in of the outboard motor does not contribute to a change in yaw of the marine vessel, that is, an improvement in the turning performance of the marine vessel. The reason why the movement of the outboard motor is mainly limited to the tilting-up and the trimming-in is that an internal combustion engine is conventionally used as a power source of the outboard motor, and it is difficult to tilt the outboard motor in a direction other than a certain direction in order to establish circulation of lubricating oil in the internal combustion engine.
As a way for achieving sustainable development goals (SDGs) proposed in recent years, implementation of carbon-free of transportation has been promoted, and replacement of a power source of a marine vessel from the internal combustion engine to an electric motor has been studied. Since the electric motor does not require lubricating oil, the restriction on the movement of the outboard motor is reduced in the case of using the electric motor as the power source as compared with the case of using the internal combustion engine as the power source, and it is considered that there is room for the movement of the outboard motor to more actively contribute to maneuverability of the marine vessel.
Preferred embodiments of the present invention provide outboard motors that are each able to more actively contribute to the maneuverability of a marine vessel.
According to a preferred embodiment of the present invention, a small marine vessel includes a hull and at least one outboard motor attached to the hull, wherein the at least one outboard motor is attached to the hull to be rotatable about a first axis extending along a front-rear direction of the hull and to be movable in an up-down direction of the hull.
According to another preferred embodiment of the present invention, a small marine vessel includes a hull and at least one outboard motor attached to the hull, wherein the at least one outboard motor includes an electric motor as a power source, and the least one outboard motor is attached to the hull to be rotatable about a first axis extending along a front-rear direction of the hull.
According to the above configuration, the outboard motor can be not only rotated about a tilt axis extending along a left-right direction of the hull but also rotated about the first axis extending along a front-rear direction of the hull. Therefore, it is possible to change an action position of a thrust force generated by the propeller of the outboard motor in the left-right direction of the hull to actively change the yaw of the marine vessel. That is, it is possible to more actively contribute the movement of the outboard motor to the maneuverability of the marine vessel.
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.
Hereinafter, preferred embodiments of the present invention will be described with reference to the drawings.
In
The outboard motor 13 includes an electric motor 15 as a power source. The electric motor 15 is disposed in an upper portion 13a of the outboard motor 13. Moreover, the outboard motor 13 includes a propeller 16 disposed in a lower portion 13b, a propeller shaft 17 configured to rotate the propeller 16, and a drive shaft 18 configured to transmit a driving force of the electric motor 15 to the propeller shaft 17. The outboard motor 13 applies a thrust force to the marine vessel 10 by the propeller 16 rotated by the driving force of the electric motor 15.
The outboard motor 13 is provided with a steering mechanism (not illustrated), and the steering mechanism swings the outboard motor 13 in a left-right direction of the hull 11 (hereinafter, “of the hull 11” is omitted and simply referred to as the “left-right direction”) with respect to the hull 11 to adjust an acting direction of the thrust force generated by the propeller 16 of the outboard motor 13 to the left and right.
Each of the outboard motors 13 is attached to the stern 12 of the hull 11 in a state of being rotatable about a roll axis 20 (first axis) extending in a front-rear direction of the hull 11 (hereinafter, “of the hull 11” is omitted and simply referred to as the “front-rear direction”). The roll axis 20 corresponds to each of the two outboard motors 13, and one outboard motor 13 rotates about its corresponding roll axis 20 independently of the other outboard motor 13 rotating about its corresponding roll axis 20.
The outboard motor 13 is attached to the stern 12 of the hull 11 in a state of being rotatable about a tilt axis 19 (second axis) extending in the left-right direction. Each of the outboard motors 13 is configured to rotate counterclockwise about the tilt axis 19 in
For example, as illustrated in
As illustrated in
In a case where the propellers 16 of the outboard motors 13 are spaced farther apart from each other (
Further, as illustrated in
When the respective outboard motors 13 do not rotate about the roll axis 20 (
On the other hand, when both of the propellers 16 of the respective outboard motors 13 move toward the port side (
Note that the outboard motors 13 may rotate about their roll axes 20 such that the respective propellers 16 move toward the starboard side. In this case, the turning performance of the marine vessel 10 toward the port side is improved.
According to the present preferred embodiment, each of the outboard motors 13 is able to be independently rotated about their roll axis 20. Therefore, positions of the action points P of the thrust forces F generated by the propellers 16 of the respective outboard motors 13 can be changed in the left-right direction of the marine vessel 10 to actively change the yaw of the marine vessel 10. That is, the movement of each of the outboard motors 13 more actively contributes to the maneuverability of the marine vessel 10.
Since the power source of each of the outboard motors 13 is the electric motor 15 in the present preferred embodiment, it is unnecessary to consider an influence of tilting of the outboard motor 13 on the circulation of lubricating oil, and a rotation amount (roll amount) of each of the outboard motors 13 about the roll axis 20 can be increased. Therefore, the positions of the action points P of the thrust forces F can be changed more greatly in the left-right direction of the marine vessel 10, and the yaw of the marine vessel 10 can be further actively changed.
Moreover, according to the present preferred embodiment, the yaw of the marine vessel 10 can be actively changed by rotating each of the outboard motors 13 about their roll axis 20. Therefore, it is unnecessary to increase an output of the electric motor 15 of each of the outboard motors 13 more than necessary in order to improve the head-turning characteristic when turning on the spot. Further, it is unnecessary to dispose the outboard motors 13 to be greatly spaced apart from each other in the left-right direction. Therefore, the outboard motors 13 can be downsized, and the degree of freedom of the layout of the outboard motors 13 is able to be improved.
Note that in each of the cases illustrated in
Next, a second preferred embodiment of the present invention will be described. The second preferred embodiment is different from the first preferred embodiment in that each of the outboard motors 13 moves also in an up-down direction of the hull 11 (hereinafter, “of the hull 11” is omitted and simply referred to as the “up-down direction”), but is basically the same as the first preferred embodiment described above in terms of the other configurations and actions thereof. The configurations and actions thereof overlapping with those of the first preferred embodiment will not be described. Hereinafter, configurations and actions of the second preferred embodiment, different from those of the first preferred embodiment, will be described.
In a case where the marine vessel 10 as a planing boat sails at a high speed, lift acting on a vessel bottom is generated, and the marine vessel 10 shifts to a planing state. In this case, the hull 11 rises, which brings the draft shallower and brings the propellers 16 closer to a water surface. Then, when the outboard motors 13 rotate about their respective roll axes 20 (
For example, as illustrated in
Further, as illustrated in
Moreover, as illustrated in
According to the present preferred embodiment, since each of the outboard motors 13 is able to be moved downward in response to the rotation of each of the outboard motors 13 about their roll axis 20, the upward movement of each of the propellers 16 caused by the rotation about the roll axis 20 is canceled which prevents each of the propellers 16 from being closer to the water surface. Therefore, it is possible to prevent the occurrence of cavitation and the occurrence of air entrainment in each of the propellers 16.
Further, in the present preferred embodiment, the rotation about the roll axis 20 and the movement in the up-down direction of the outboard motor 13 are performed independently. In this case, two actuators including an actuator for the rotation and an actuator for the movement in the up-down direction are required. Therefore, in order to reduce the number of actuators, the marine vessel 10 may be provided with a link mechanism that tilts the outboard motor 13 toward the left-right direction with respect to the up-down direction along with the movement of the outboard motor 13 in the up-down direction.
The link mechanism 21 includes a curved or J-shaped guide rail 22 and two cylindrical guides 23 that are loosely engaged with the guide rail 22 and are configured to be movable along the guide rail 22. The guide rail 22 is provided on the stern 12 of the hull 11 so that a linear portion in an upper portion of the guide rail 22 extends along the up-down direction, and a curved portion in a lower portion of the guide rail 22 is offset from the upper linear portion in the left-right direction as it extends downward. Further, each of the guides 23 is provided on the front side (which faces the stern 12) of the outboard motor 13 so as to protrude forward (toward the marine vessel 10 side). Furthermore, the guides 23 are arranged along the center line CL1 extending in the up-down direction of the outboard motor 13.
In the link mechanism 21, as illustrated in
In the link mechanism 21, the outboard motor 13 can be tilted toward the left-right direction with respect to the up-down direction along with the movement of the outboard motor 13 in the up-down direction. Therefore, it is possible to change the positions of the action points P of the thrust forces F generated by the propellers 16 in the left-right direction, thus actively changing the yaw of the marine vessel 10. Further, in the link mechanism 21, the outboard motor 13 can be tilted toward the left-right direction with respect to the up-down direction only by the actuator for moving the outboard motor 13 in the up-down direction, and thus, the number of actuators to be used is reduced.
Note that in the link mechanism 21, the outboard motor 13 does not rotate about the roll axis 20. However, an angle θ (rotation angle about the roll axis 20) formed by a normal line extending from the roll axis 20 to the center line CIA_ and the left-right direction is larger than 0° when the outboard motor 13 is tilted toward the left-right direction (in
Further, the guide rail 22 is provided on the stern 12 of the hull 11 such that the linear portion in the upper portion is disposed along the up-down direction, but the linear portion in the upper portion may be slightly tilted toward the left-right direction with respect to the up-down direction.
In each of the cases illustrated in
When the marine vessel 10 turns, the hull 11 rolls so that one outboard motor 13 out of the left and right outboard motors 13 is lifted, and the propeller 16 of the lifted outboard motor 13 comes closer to the water surface. In this case, as illustrated in
A third preferred embodiment of the present invention will be described. The third preferred embodiment is different from the first preferred embodiment in that each of the outboard motors 13 is not only rotated about the roll axis 20 but also rotated about the tilt axis 19, but is basically the same as the first preferred embodiment described above in terms of the other configurations and actions thereof. The configurations and actions thereof overlapping with those of the first preferred embodiment will not be described. Hereinafter, configurations and actions thereof of the third preferred embodiment, different from those of the first preferred embodiment, will be described.
When the outboard motor 13 on the port side is trimmed in, the thrust force F on the port side acts obliquely upward on the hull 11, and an upward component force f is generated (FIG. The component force f lifts the port side of the hull 11. That is, a roll moment M4 to tilt the hull 11 to the starboard side is generated by the component force f (
Although the outboard motor 13 on the starboard side does not rotate about the tilt axis 19 in
For example, as illustrated in
Further, as illustrated in
Moreover, when the marine vessel 10 turns to the starboard side, in order to generate a yaw moment that facilitates turning to the starboard side, each of the outboard motors 13 is turned about their respective roll axis 20 such that the propellers 16 of the respective outboard motors move toward the port side as illustrated in
Note that in a case where the marine vessel 10 is traveling at a low speed, the hull 11 is likely to tilt toward the starboard side when each of the outboard motors 13 is rotated about their respective roll axis 20 such that the propellers 16 of the respective outboard motors move toward the starboard side when the marine vessel 10 turns to the port side. In this case, the outboard motor 13 on the starboard side is trimmed in to generate a roll moment to tilt the hull 11 toward the port side.
According to the present preferred embodiment, since the outboard motor 13 on the side of the hull 11 sinking into the water is trimmed in in response to a tilt toward one side of the hull 11, the roll moment M4 that cancels the tilt is generated, and thus, the ride comfort is able to be improved.
Note that it is assumed that the rotation angle about the tilt axis 19 of the outboard motor 13 on the starboard side is different from the rotation angle about the tilt axis 19 of the outboard motor 13 on the port side in the present preferred embodiment, but these rotation angles may be the same. Further, each of the outboard motors 13 may be moved in the up-down direction as in the second preferred embodiment. In this case, amounts of downward movement of the left and right outboard motors 13 may be the same or different from each other.
Although preferred embodiments of the present invention have been described above, the present invention is not limited to the above-described respective preferred embodiments, and various modifications and changes can be made within the scope of the gist of the present invention. For example, the outboard motor 13 of each of the above-described preferred embodiments includes the electric motor 15 as the power source. However, the outboard motor 13 may include, as the power source, for example, a rotary engine which is an internal combustion engine in which the circulation of lubricating oil is established even when the outboard motor 13 is greatly rotated about the roll axis 20, or a reciprocating engine that is able to suck up lubricating oil from an oil pan by a strainer even with a large tilt.
Although preferred embodiments of the present invention have been applied to the marine vessel 10 including the outboard motors 13, the present invention may be applied to a small marine vessel including at least one inboard/outboard motor.
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 |
---|---|---|---|
2022-094002 | Jun 2022 | JP | national |