An aspect of the present disclosure relates to a personal watercraft.
Personal watercrafts are widely used for various purposes, such as for leisure activities, sport activities, and rescue activities. There is a known personal watercraft that includes a light emitter mounted on the body of the personal watercraft and configured to emit light when the personal watercraft is in operation (see U.S. Pat. No. 5,850,803 A, for example).
A personal watercraft according to an aspect of the present disclosure includes: a watercraft body including a hull and a deck covering an upper portion of the hull; a light emitter supported by the watercraft body; and a protection cover covering the light emitter and permeable to light emitted by the light emitter, wherein the watercraft body includes a flow-regulating structure, and the flow-regulating structure includes: a fluid inlet through which an external fluid enters the watercraft body; and an upper flow-regulating wall and a lower flow-regulating wall that are opposed to each other in an up-down direction, the upper and lower flow-regulating walls being located between the fluid inlet and the protection cover to regulate flow of the fluid entering the watercraft body through the fluid inlet and moving toward the protection cover.
In the above configuration, the flow of the fluid entering the watercraft body through the fluid inlet and moving toward the protection cover is regulated by the upper and lower flow-regulating walls. Thus, the angle of the direction of fluid flow toward the protection cover with respect to the horizontal plane is controlled. This makes it easier to design a light emitter-protecting structure capable of withstanding winds and waves.
The above and further objects, features and advantages of the present disclosure will be more apparent from the following detailed description of preferred embodiments with reference to the accompanying drawings.
Hereinafter, exemplary embodiments will be described with reference to the drawings.
The watercraft body 2 includes a hull 11 and a deck 12 covering the upper portion of the hull 11. Referring to
A water inlet 11a opens at the bottom of the hull 11. The water inlet 11a and the pump casing 4d are in communication via a water passage 11b. The pump casing 4d is provided with a pump nozzle 4e facing rearward of the watercraft body 2. The pump nozzle 4e decreases in diameter from front to rear, and an ejection orifice opens at the rear end of the pump nozzle 4e. To the ejection orifice of the pump nozzle 4e is connected a steering nozzle 5 which is swingable in the right-left direction. A bowl-shaped reverse bucket 6 is located in the vicinity of the steering nozzle 5. The reverse bucket 6 is pivotally supported by the hull 11 and pivotable between an advanced position where the reverse bucket 6 covers the ejection orifice of the steering nozzle 5 from behind to cause water ejected from the pump nozzle 4e to be redirected forward and a retracted position where the reverse bucket 6 allows the ejection orifice of the steering nozzle 5 to be open in the rearward direction.
In the personal watercraft 1, water drawn into the hull 11 through the water inlet 11a located at the bottom of the hull 11 is pressurized and accelerated by rotational power of the impeller 4b of the water jet pump 4 driven by the engine 3. The flow of water is regulated by the stator vane 4c and ejected rearward through the ejection orifice of the pump nozzle 4e and the steering nozzle 5 to produce propulsion power. A bar-shaped handle 7 is located above the front of the deck 12 and rotatably supported by the deck 12. When the operator tilts the handle 7 to the right or left, the steering nozzle 5 swings to the right or left in conjunction with the tilting movement of the handle 7.
The deck 12 includes a seat support 12a and a pair of foot rests 12b. The seat support 12a is located rearward of the handle 7 and projects upward from the deck floor on which users can walk. Referring to
In the deck 12, a meter device 22 is disposed forward of the handle 7. The meter device 22 is covered from above by a meter cover 23. An openable hatch cover 24 is disposed forward of the meter cover 23.
Two light units 25 are disposed on a front end portion of the watercraft body 2. As seen from
The watercraft body 2 includes a front bumper 13, two side bumpers 14, and a rear bumper 15. The bumpers 13, 14, and 15 are placed to cover the region where the hull 11 and the deck 12 are connected. The front bumper 13 is located forward of the hatch cover 24. The front bumper 13 is located forward of and covers the front end portions of the hull 11 and the deck 12. The side bumpers 14 are located lateral to and cover the side edge portions of the hull 11 and the deck 12. The rear bumper 15 is located rearward of and covers the rear end portions of the hull 11 and the deck 12. Each of the bumpers 13, 14, and 15 is made of an elastically deformable material. For example, when exposed to an external force such as that arising from collision with an object floating on the water, the bumpers 13, 14, and 15 are elastically deformed (bent) to absorb the external force.
The front bumper 13 includes an outer upper wall 31 facing obliquely forward and upward and an outer lower wall 32 facing obliquely forward and downward. As seen from
The front bumper 13 is placed to surround the peripheries of the two light units 25. As seen from
In the present embodiment, each light passageway P is formed such that fluids such as air and water can spontaneously enter the light passageway P from outside the watercraft body 2 (in particular, from outside the front bumper 13). A fluid entering the light passageway P from outside the watercraft body 2 collides with the light unit 25. The front bumper 13 includes a flow-regulating structure 33 that regulates the flow of a fluid entering the light passageway P from outside the watercraft body 2 (in particular, from outside the front bumper 13) and moving toward the light unit 25 through the light passageway P.
The flow-regulating structure 33 is configured to allow a fluid coming from outside the watercraft body 2 to collide with the light unit 25 in a predetermined direction. The flow-regulating structure 33 includes a fluid inlet 34, an upper flow-regulating wall 35a, a lower flow-regulating wall 35b, a right flow-regulating wall 35c, and a left flow-regulating wall 35d.
The fluid inlet 34 is an opening formed in the outer upper wall 31. The fluid coming from outside the watercraft body 2 enters the light passageway P through the fluid inlet 34. In the present embodiment, the fluid inlet 34 serves as the entrance to the light passageway P for the fluid coming from outside the watercraft body 2 and as the exit from the light passageway P for light emitted by the light unit 25.
The flow-regulating structure 33 constituting a part of the front bumper 13 is located around the light unit 25 and configured to project in a horizontal direction (the forward direction in this example) toward the outside of the watercraft body 2 and surround the periphery of the light unit 25. When seen from outside the watercraft body 2, the light unit 25 (in particular, a protection cover 42 described later) is visible only through the fluid inlet 34. When a fluid is coming from outside the watercraft body 2 (in particular, from outside the front bumper 13), that portion of the fluid which enters the light passageway P through the fluid inlet 34 is directed to the light unit 25, while the rest of the fluid is prevented by the flow-regulating structure 33 from flowing toward the light unit 25.
The upper flow-regulating wall 35a and the lower flow-regulating wall 35b are opposed to each other in the up-down direction. The upper and lower flow-regulating walls 35a and 35b are located between the fluid inlet 34 and the light unit 25 (in particular, the protection cover 42). The upper and lower flow-regulating walls 35a and 35b regulate the flow of a fluid entering the light passageway P through the fluid inlet 34 and moving toward the light unit 25. In other words, the fluid entering the light passageway P through the fluid inlet 34 is guided by the upper and lower flow-regulating walls 35a and 35b to pass between the upper and lower flow-regulating walls 35a and 35b toward the light unit 25.
The right flow-regulating wall 35c and the left flow-regulating wall 35d are opposed to each other in the right-left direction. The right and left flow-regulating walls 35c and 35d are located between the fluid inlet 34 and the light unit 25 (in particular, the protection cover 42). The right and left flow-regulating walls 35c and 35d regulate the flow of a fluid entering the light passageway P through the fluid inlet 34 and moving toward the light unit 25. In other words, the fluid entering the light passageway P through the fluid inlet 34 is guided by the right and left flow-regulating walls 35c and 35d to pass between the right and left flow-regulating walls 35c and 35d toward the light unit 25.
The configuration of that part of the personal watercraft 1 which is in the vicinity of the left light unit 25 will be described in detail with reference to
The deck 12 includes a mounting wall 51 on which the light unit 25 (in particular, a base 43 described later) is mounted. The mounting wall 51 includes a first wall surface 51a which is a flat surface facing toward the outside of the watercraft body 2 and a second wall surface 51b which is a flat surface facing toward the inside of the watercraft body 2. The light unit 25 is mounted on the first wall surface 51a of the mounting wall 51.
The light unit 25 is made up of a plurality of light emitters 41, a protection cover 42, a base 43, and a light-side connector 45 which are integrated into a single unit. The light unit 25 is in an elongated shape extending longitudinally in the right-left direction (see also
Each light emitter 41 is, for example, a light-emitting diode (LED). The light emitter 41 need not be an LED and may be any existing light-emitting source. For example, the light emitter 41 may be an incandescent lamp or an organic or inorganic electro-luminescent (EL) element. The light emitters 41 are supported by the base 43 on the watercraft body 2. The light emitters 41 are not limited to a particular manner of arrangement. For instance, as in the illustrated example, the light emitters 41 may be arranged in a straight line extending in the right-left direction. The light emitters 41 may be spaced apart from one another. The light unit 25 need not include two or more light emitters 41 and may include only one light emitter 41.
The protection cover 42 covers the plurality of light emitters 41 from outside the watercraft body 2, in particular from the front. The protection cover 42 is permeable to light emitted by the light emitters 41 and impermeable to water and air. The protection cover 42 is made of, for example, a transparent or semi-transparent resin. The protection cover 42 is generally in the shape of a box opening toward the inside of the watercraft body 2. For example, as shown in
The base 43 connects and secures the light emitters 41 and the protection cover 42 to the deck 12. Specifically, the base 43 is located between the mounting wall 51 of the deck 12 and the light emitters 41. The base 43 includes a first base surface which is a flat surface facing toward the inside of the watercraft body 2 and a second base surface which is a flat surface facing toward the outside of the watercraft body 2. The first base surface is a flat surface which is in contact with the first wall surface 51a of the mounting wall 51. The first base surface need not be a flat surface and may be any surface conforming to the first wall surface 51a.
The base 43 is secured to the mounting wall 51 by fasteners, with the first base surface and the first wall surface 51a being in surface contact. For example, the fasteners include: stud bolts 43b inserted through holes provided in the mounting wall 51 of the deck 12 and holes provided in right and left ends of the base 43; and nuts (not shown) threaded on the stud bolts 43b.
The light emitters 41 are secured to the second base surface. The second base surface is provided with a joining portion which surrounds the light emitters 41 when viewed in a direction perpendicular to the second base surface. The joining portion is where the protection cover 42 is joined to the base 43. For example, as shown in
The mounting wall 51 is provided with a through hole 51c. The base 43 is provided with a projecting portion 44 projecting from the first base surface of the base 43 toward the inside of the watercraft body 2, the projecting portion 44 being inserted through the through hole 51c. The projecting portion 44 is provided with the light-side connector 45. The projecting portion 44 may be integral with the base 43 or light-side connector 45 or may be an entity separate from the base 43 and the light-side connector 45. The light-side connector 45 is connected to a watercraft body-side connector 52 described later. The projecting portion 44 is configured to establish electrical connection between the light-side connector 45 and the light emitters 41. Specifically, the projecting portion 44 includes a conductor electrically connecting the light-side connector 45 to the light emitters 41.
Referring to
The watercraft body-side connector 52 is secured to the deck 12 (for example, to the second wall surface 51b of the mounting wall 51) by, for example, a fastening member 54. The light unit 25 is placed on the first wall surface 51a of the mounting wall 51 in such a manner that the projecting portion 44 is inserted through the through hole 51c. Thus, the light-side connector 45 and the watercraft body-side connector 52 are connected to enable supply of electric power from the electric power supply 53 to the light emitters 41.
In
Referring to
As shown in
The lower flow-regulating wall 35b is shaped to be generally parallel to the horizontal plane. The lower flow-regulating wall 35b may be inclined upward in the rearward direction. The lower flow-regulating wall 35b may be made up of a plurality of flat plates coupled together such that the angle of the lower flow-regulating wall 35b with respect to the horizontal plane decreases in the rearward direction. Alternatively, the lower flow-regulating wall 35b may be embodied by a single flat plate positioned at a fixed angle with respect to the horizontal plane.
The rear edges of the upper and lower flow-regulating walls 35a and 35b overlap the outer surface 42a of the protection cover 42 in front view. In other words, as shown in
The upper and lower flow-regulating walls 35a and 35b regulate the flow of a fluid entering the light passageway P through the fluid inlet 34 and moving toward the protection cover 42. Thus, the direction in which the fluid entering the light passageway P through the fluid inlet 34 flows toward the protection cover 42 is controlled. More specifically, the angle of the direction of fluid flow from the fluid inlet 34 toward the protection cover 42 with respect to the horizontal plane is controlled by the upper and lower flow-regulating walls 35a and 35b.
As seen from
The left flow-regulating wall 35d, which is located outward of the right flow-regulating wall 35c in the watercraft body width direction, is inclined to extend obliquely rearward toward the center of the watercraft body 2. The right flow-regulating wall 35c may be made up of a plurality of flat plates coupled together such that the angle of the right flow-regulating wall 35c with respect to a plane perpendicular to the first wall surface 51a decreases in the rearward direction. Alternatively, the right flow-regulating wall 35c may be embodied by a single flat plate positioned at a fixed angle with respect to the plane perpendicular to the first wall surface 51a.
The rear edges of the right and left flow-regulating walls 35c and 35d overlap the outer surface 42a of the protection cover 42 when viewed in a direction perpendicular to the first wall surface 51a. In other words, as seen from
The right and left flow-regulating walls 35c and 35d regulate the flow of a fluid entering the light passageway P through the fluid inlet 34 and moving toward the protection cover 42. Thus, the direction in which the fluid entering the light passageway P through the fluid inlet 34 flows toward the protection cover 42 is controlled. More specifically, the angle of the direction of fluid flow from the fluid inlet 34 toward the protection cover 42 with respect to the vertical plane (e.g., a plane perpendicular to the first wall surface 51a) is controlled by the right and left flow-regulating walls 35c and 35d.
A gap g is provided between the protection cover 42 and the rear edge of each of the flow-regulating walls 35a, 35b, 35c, and 35d in the front-rear direction (in particular, the direction perpendicular to the first wall surface 51a). The size of the gap g between the protection cover 42 and the rear edge of each of the flow-regulating walls 35a, 35b, 35c, and 35d need not be constant, and there may be a difference between the distance from one portion of the rear edge to the protection cover 42 and the distance from another portion of the rear edge to the protection cover 42. The size of the gap g in the direction perpendicular to the first wall surface 51a is, for example, 10 mm or less and preferably 5 mm or less.
The gap g serves as an exit for a fluid entering the light passageway P through the fluid inlet 34. For example, a fluid entering the light passageway P through the fluid inlet 34 during forward movement of the personal watercraft 1 passes through the gap g and flows rearward along the outer surface of the deck 12. When the front bumper 13 is subjected to an external force, transmission of the external force from the front bumper 13 to the protection cover 42 can be reduced since the front bumper 13 and the protection cover 42 are spaced apart.
In the configuration described above, the flow-regulating structure 33 controls the angle of the direction of fluid flow toward the protection cover 42 with respect to the horizontal and vertical planes. This makes it easier to design a protection structure for the light emitters 41 which is capable of withstanding winds and waves.
Additionally, since the overhang E of the front bumper 13 covers the upper portion of the protection cover 42, the direction of flow of a fluid coming from above and moving toward the protection cover 42 can be controlled.
Additionally, since the outer surface 42a of the protection cover 42, which faces toward the fluid inlet 34, extends perpendicular to the horizontal plane when the watercraft body 2 is at rest on the water, the variety of possible directions in which loads can be applied to the protection cover 42 is reduced. This allows for a simplified design of the load bearing structure of the protective member for the light emitters 41.
Additionally, in the present embodiment, the flow-regulating structure 33 is provided in the front bumper 13. This eliminates the need for additionally mounting a member including the flow-regulating structure 33 on the watercraft body 2. Further, the front bumper 13 can prevent contact of objects floating on the water with the protection cover 42.
Additionally, since the outer surface 42a of the protection cover 42, which faces toward the fluid inlet 34, extends rearward with increasing distance from the center plane C dividing the watercraft body 2 into right and left halves, a fluid colliding with the front of the protection cover 42 during forward movement of the personal watercraft 1 can easily be directed rearward. This can reduce the pressure applied to the protection cover 42 by the fluid.
Additionally, since the light emitters 41, the protection cover 42, and the base 43 are integrated into a light unit, the light emitters 41 and the protection cover 42 are easy to mount on the watercraft body 2.
Additionally, the base 43 is secured to the mounting wall 51 with the first base surface of the base 43 in contact with the first wall surface 51a of the mounting wall 51. Thus, a load applied to the protection cover 42 from a fluid is borne by the surface of the deck 12 via the base 43. This allows for a protection structure for the light emitters 41 which exhibits an increased strength against fluids.
Additionally, since the watercraft body-side connector 52 and the light-side connector 45 are located in the interior of the watercraft body 2, namely in the space lying between the hull 11 and the deck 12, the watercraft body-side connector 52 and the light-side connector 45 can be reliably protected.
Many modifications and other embodiments of the present invention will be apparent to those skilled in the art from the foregoing description. Accordingly, the foregoing description is to be construed as illustrative only, and is provided for the purpose of teaching those skilled in the art the best mode for carrying out the invention. The details of the structure and/or function may be varied substantially without departing from the scope of the invention.
For example, while in the embodiment described above the flow-regulating structure 33 includes four flow-regulating walls 35a, 35b, 35c, and 35d, the flow-regulating structure 33 need not include the right and left flow-regulating walls 35c and 35d. When the flow-regulating structure 33 does not include the right and left flow-regulating walls 35c and 35d, the fluid inlet 34 may be in the shape of a slit extending in the right-left direction. Even in this case, the flow-regulating structure 33 including the upper and lower flow-regulating walls 35a and 35b controls the angle of the direction of fluid flow toward the protection cover 42 at least with respect to the horizontal plane. This makes it easier to design a protection structure for the light emitters 41 which is capable of withstanding winds and waves. Likewise, the flow-regulating structure 33 need not include the upper and lower flow-regulating walls 35a and 35b. When the flow-regulating structure 33 does not include the upper and lower flow-regulating walls 35a and 35b, the fluid inlet 34 may be in the shape of a slit extending in the up-down direction. Even in this case, the flow-regulating structure 33 including the right and left flow-regulating walls 35c and 35d controls the angle of the direction of fluid flow toward the protection cover 42 at least with respect to the vertical plane (e.g., a plane perpendicular to the first wall surface 51a). This makes it easier to design a protection structure for the light emitters 41 which is capable of withstanding winds and waves.
The light emitters 41 and protection cover 42 need not be disposed on the front end portion of the watercraft body 2, and may be disposed, for example, on the side edge portion or rear end portion of the watercraft body 2. The flow-regulating structure 33 may be provided in the side bumper 14 or rear bumper 15, instead of or in addition to being provided in the front bumper 13. That is, the flow-regulating structure 33 is not limited to a structure which controls the direction of flow of a fluid coming from the front of the watercraft body 2 and moving toward the protection cover 42, and may be a structure which controls the direction of flow of a fluid coming from the side or rear of the watercraft body 2 and moving toward the protection cover 42. In this case, the gap g between the protection cover 42 and that edge of each of the flow-regulating walls 35a, 35b, 35c, and 35d which faces toward the inside of the watercraft body 2 need not be provided in the front-rear direction, and may be provided in a direction toward the center of the watercraft body 2 (e.g., a direction perpendicular to the outer surface 42a of the protection cover 42). There may be no gap between the protection cover 42 and that edge of each of the flow-regulating walls 35a, 35b, 35c, and 35d which faces toward the inside of the watercraft body 2.
While in the embodiment described above the flow-regulating structure 33 is provided in the front bumper 13, the flow-regulating structure 33 may be provided in none of the bumpers 13, 14, and 15. For example, the watercraft body 2 may include a member distinct from the bumpers and including the flow-regulating structure 33. The side bumper 14 is smaller in size in the up-down direction than the front bumper 13 and the rear bumper 15 and, in some cases, the size of the side bumper 14 in the up-down direction is so small that the side bumper 14 cannot cover the protection cover 42. Thus, if the flow-regulating structure 33 is provided in a side edge portion of the watercraft body 2, it is preferable that a member distinct from the side bumper 14 and including the flow-regulating structure 33 be additionally provided in the deck 12 or hull 11. The flow-regulating structure 33 need not be provided in a member to be secured to the deck 12 and, for example, the deck 12 itself may include the flow-regulating structure 33.
The outer surface 42a of the protection cover 42 may be inclined with respect to the vertical direction. For example, the outer surface 42a of the protection cover 42, which faces toward the fluid inlet 34, may be inclined with respect to the vertical direction when the watercraft body 2 is at rest on the water. In this case, the angle of inclination of the outer surface 42a with respect to the vertical direction is preferably 10 degrees or less. With such an angle of inclination, the outer surface 42a of the protection cover 42 which faces toward the fluid inlet 34 can be positioned to extend substantially in the vertical direction. Thus, the variety of possible directions in which loads can be applied to the protection cover 42 is reduced. This allows for a simplified design of the load bearing structure of the protective member for the light emitters 41.
The light units 25 need not be located between the upper and lower edges of the front bumper 13 in the up-down direction. It is particularly preferable to provide the flow-regulating structure 33 when in the personal watercraft 1 the protection cover 42 and/or the light emitters 41 are located at a height where they might be exposed to waves or wave splashes, such as when the protection cover 42 and/or the light emitters 41 are located below the highest point of the upper surface of the seat 8 in side view.
The outer surface 42a of the protection cover 42, which faces toward the fluid inlet 34, may be parallel or perpendicular to the center plane C of the watercraft body 2 in top view.
The light emitters 41, the protection cover 42, and the base 43 need not be integrated into a light unit. For example, a base supporting the light emitters 41 and a base supporting the protection cover 42 may be separately provided, and these bases may be individually secured to the deck 12.
The deck 12 need not include the mounting wall 51 on which the base 43 is mounted, and the base 43 may be mounted on a member supported by the deck 12.
Number | Name | Date | Kind |
---|---|---|---|
4694770 | Kitner | Sep 1987 | A |
5850803 | Jones | Dec 1998 | A |
6712018 | Cassell | Mar 2004 | B2 |
10457358 | Granata | Oct 2019 | B1 |