[0001] The present invention relates to an outboard motor capable of being tilted up and
trimmed in, and a marine vessel therewith.
[0002] A relatively small marine vessel such as a planing boat has an outboard motor as
a propulsion device. As shown in FIG. 9A, an outboard motor 90 includes an outboard
motor main body 91 incorporating a power source therein, and a bracket 93 provided
with a tilt shaft 92. The bracket 93 is attached to a stern 98 of a hull 94 of a marine
vessel, and the outboard motor main body 91 is attached to the bracket 93 so as to
rotate about the tilt shaft 92. Note that in FIG. 9A to FIG. 9C, the left side in
the figures corresponds to a forward direction of the marine vessel, the right side
in the figures corresponds to a rearward direction of the marine vessel, the upper
side in the figures corresponds to an upper direction of the marine vessel, and the
lower side in the figures corresponds to a lower direction of the marine vessel. The
tilt shaft 92 extends in the crosswise direction of the marine vessel, and hence the
outboard motor main body 91 rotates about the tilt shaft 92 counterclockwise as viewed
in the drawing (tilt-up) such that an upper portion 91a moves forward and downward
and a lower portion 91b moves rearward and upward (FIG. 9A), or rotates about the
tilt shaft 92 clockwise as viewed in the drawing (trim-in) such that the upper portion
91a moves rearward and downward and the lower portion 91b moves forward and upward
(FIG. 9B) (see, for example,
Japanese Laid-open Patent Publication (Kokai) No. H01-317893).
[0003] Conventionally, a reciprocating engine 95, which is an internal combustion engine,
has been used as a power source for the outboard motor 90. In an upper portion 91a
of the outboard motor main body 91, the reciprocating engine 95 is disposed such that
a crankshaft lies along the vertical direction and a cylinder head 96 lies behind
a cylinder block 97 (FIG. 9A). Thus, when the outboard motor main body 91 is trimmed
in to a great extent, at least a part of the cylinder head 96 becomes positioned at
a lower position than the cylinder block 97. Therefore, lubricating oil for a cylinder
in the cylinder block 97 may be burned in a fuel chamber without going back to a crankcase,
and as a result, the reciprocating engine 95 may blow white smoke. For this reason,
in the outboard motor 90 using the reciprocating engine 95, it is difficult for the
outboard motor main body 91 to trim in to a great extent.
[0004] Implementation of carbon-free mobile bodies as one of means for achieving recently-advocated
SDGs (Sustainable Development Goals) has been pursued, and as a power source for an
automobile which is as an example of mobile bodies, an internal combustion engine
is being increasingly replaced with an electric motor.
[0005] As the power source of the outboard motor 90, it has also been studied to replace
an internal combustion engine with an electric motor as with the automobile. If the
power source of the outboard motor 90 is replaced with an electric motor, the combustion
of the lubricating oil described above will never happen, which will make it unnecessary
to limit the amount of trim-in so as to prevent the white smoke. Trim-in has a significant
effect on posture control in the pitch direction while the marine vessel is sailing,
and hence in the outboard motor 90 using an electric motor as the power source, the
outboard motor main body 91 is required to be trimmed in to a great extent from the
standpoint of increasing the degree of freedom in posture control.
[0006] On the other hand, for the conventional outboard motor 90, the outboard motor main
body 91 is required to be tilted up to a great extent since priority is given to lifting
the outboard motor main body 91 out of water when the marine vessel is anchored at
a pier or the like for a long period of time. Accordingly, in a conventional technique,
by placing the tilt shaft 92 in the vicinity of the upper portion 91a of the outboard
motor main body 91, even if the outboard motor main body 91 is tilted up to a great
extent, the amount of movement to forward of the upper portion 91a of the outboard
motor main body 91 is kept small so that the upper portion 91a of the outboard motor
main body 91 is prevented from interfering with the hull 94 (FIG. 9B).
[0007] However, if the tilt shaft 92 is placed in the vicinity of the upper portion 91a
of the outboard motor main body 91, the lower portion 91b of the outboard motor main
body 91 moves forward by a large amount when the outboard motor main body 91 is trimmed
in, and therefore, even when the amount of trim-in is increased only a little, the
lower portion 91b of the outboard motor main body 91 may interfere with the hull 94
(FIG. 9C). Thus, in the conventional outboard motor 90, it is difficult to increase
the amount (angle) of the trim-in of the outboard motor main body 91, and the outboard
motor main body 91 is allowed to be trimmed in up to only about 4° about the tilt
shaft 92. Namely, there is room for improvement regarding the amount of trim-in that
can be achieved.
[0008] It is the object of the present invention to provide an outboard motor that can achieve
a great trim-in of the main body of the outboard motor.
[0009] According to the present invention said object is solved by an outboard motor having
the features of the independent claim 1. As an alternative solution of said object,
it is provided an outboard motor having the features of the independent claim 12 or
an outboard motor having the features of the independent claim 13. Preferred embodiments
are laid down in the dependent claims.
[0010] According to a preferred embodiment, an outboard motor comprising a main body that
incorporates a power source therein, and a bracket that includes a rotating shaft,
wherein the bracket is to be attached to a stern of a hull of a marine vessel, wherein:
the main body is attached to the bracket so as to be able to rotate a first rotation
and a second rotation; a propeller shaft for rotating a propeller is provided at a
lower portion of the main body; in the first rotation, the main body rotates about
the rotating shaft such that an upper portion of the main body moves toward the front
of the marine vessel and a lower portion of the main body moves toward the rear of
the marine vessel; in the second rotation, the main body rotates about the rotating
shaft such that the upper portion of the main body moves toward the rear of the marine
vessel and the lower portion of the main body moves toward the front of the marine
vessel; and while the marine vessel is sailing, a first distance from the rotating
shaft to an upper end of the stern with respect to a vertical direction of the marine
vessel is equal to or longer than a second distance from the rotating shaft to the
propeller shaft with respect to the vertical direction of the marine vessel.
[0011] According to another preferred embodiment, an outboard motor comprising a main body
that incorporates a power source therein, and a bracket that includes a rotating shaft,
wherein the bracket is to be attached to a stern of a hull of a marine vessel, wherein:
the main body is attached to the bracket so as to be able to rotate a first rotation
and a second rotation; in the first rotation, the main body rotates about the rotating
shaft such that an upper portion of the main body moves toward the front of the marine
vessel and a lower portion of the main body moves toward the rear of the marine vessel;
in the second rotation, the main body rotates about the rotating shaft such that the
upper portion of the main body moves toward the rear of the marine vessel and the
lower portion of the main body moves toward the front of the marine vessel; and with
respect to a vertical direction of the marine vessel, the rotating shaft is disposed
closer to a lower end of the stern than to an upper end of the stern.
[0012] According to another preferred embodiment, an outboard motor comprising a main body
that incorporates a power source therein, and a bracket that includes a rotating shaft,
wherein the bracket is to be attached to a stern of a hull of a marine vessel, wherein:
the main body is attached to the bracket so as to be able to rotate a first rotation
and a second rotation; in the first rotation, the main body rotates about the rotating
shaft such that an upper portion of the main body moves toward the front of the marine
vessel and a lower portion of the main body moves toward the rear of the marine vessel;
in the second rotation, the main body rotates about the rotating shaft such that the
upper portion of the main body moves toward the rear of the marine vessel and the
lower portion of the main body moves toward the front of the marine vessel; and with
respect to a vertical direction of the marine vessel, the rotating shaft is disposed
closer to a lower end of the main body than to an upper end of the main body.
[0013] According to the configuration described above,: while the marine vessel is sailing,
the first distance from the rotating shaft to the upper end of the stern with respect
to the vertical direction of the marine vessel is equal to or longer than the second
distance from the rotating shaft to the propeller shaft with respect to the vertical
direction of the marine vessel; the rotating shaft is disposed closer to the lower
end of the stern than to the upper end of the stern with respect to the vertical direction
of the marine vessel; or the rotating shaft is disposed closer to the lower end of
the main body than to the upper end of the main body with respect to the vertical
direction of the marine vessel. Namely, the rotating shaft of the main body of the
outboard motor is disposed closer to the bottom with respect to the vertical direction
of the marine vessel. Therefore, the amount of the forward movement of the lower portion
of the main body when the outboard motor is rotated about the rotating shaft such
that the lower portion of the main body of the outboard motor moves forward of the
marine vessel (trimmed in) is small, and hence even if the amount of trim-in is increased,
the lower portion of the main body can be prevented from interfering with the hull.
As a result, the main body of the outboard motor can be trimmed in to a great extent.
[0014] Further features of the present teaching will become apparent from the following
description of a preferred embodiment (with reference to the attached drawings).
[0015] The above and other elements, features, steps, characteristics and advantages of
the present teaching will become more apparent from the following detailed description
of the preferred embodiment with reference to the attached drawings.
BRIEF DESCRIPTION OF THE DRAWINGS
[0016]
FIG. 1 is a side view of a marine vessel to which an outboard motor according to a
first preferred embodiment is applied.
FIG. 2 is a side view useful in explaining the outline of a configuration of the outboard
motor according to the first preferred embodiment.
FIGS. 3A to 3C are views useful in explaining trim-in and tilt-up of an outboard motor
main body in the first preferred embodiment.
FIGS. 4A to 4C are views useful in explaining shift of a state of a planing boat equipped
with an outboard motor including a conventional reciprocating engine to a planing
state.
FIGS. 5A to 5C are views useful in explaining a shift of a state of a marine vessel
equipped with an outboard motor including an electric motor according to the first
preferred embodiment, to the planing state.
FIG. 6 is a side view of a marine vessel to which an outboard motor according to a
second preferred embodiment is applied.
FIG. 7 is a side view useful in explaining the outline of a configuration of the outboard
motor according to the second preferred embodiment.
FIGS. 8A to 8C are views useful in explaining trim-in and tilt-up of an outboard motor
main body in the second preferred embodiment.
FIGS. 9A to 9C are views useful in explaining trim-in and tilt-up of a conventional
outboard motor main body.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS
[0017] Hereafter, preferred embodiments will be described with reference to the drawings.
A description will now be given of a first preferred embodiment.
[0018] FIG. 1 is a side view of a marine vessel 10 to which an outboard motor 13 according
to the first preferred embodiment is applied. FIG. 2 is a side view useful in explaining
the outline of a configuration of the outboard motor 13 according to the first preferred
embodiment.
[0019] The marine vessel 10 is, for example, a plaining boat, and includes a hull 11 and
at least one, for example, two outboard motors 13 as marine propulsion devices to
be attached to a stern 12 of the hull 11. A cabin 14 also serving as a cockpit is
disposed in the hull 11. Although FIG. 1 shows the marine vessel 10 in a plaining
state, the marine vessel 10 is not limited to a planing boat, but may be, for example,
a relatively small marine vessel of a displacement type.
[0020] Note that in the drawings to be referred to below, the left side in the figures corresponds
to a forward direction of the marine vessel 10, the right side in the figures corresponds
to a rearward direction of the marine vessel 10, the upper side in the figures corresponds
to an upper direction of the marine vessel 10, and the lower side in the figures corresponds
to a lower direction of the marine vessel 10, a depth direction in the figures corresponds
to a right direction of the marine vessel 10, and a front direction in the figures
corresponds to a left direction of the marine vessel 10.
[0021] The outboard motor 13 includes an outboard motor main body 16 incorporating an electric
motor 15 as a power source therein, a bracket 18 provided with a tilt shaft 17 (rotating
shaft), and a lift mechanism 19 attached to the stern 12 of the hull 11. In the outboard
motor main body 16, the electric motor 15 is disposed in an upper portion 16a. The
outboard motor main body 16 further includes a propeller 20 and a propeller shaft
21 for rotating the propeller 20, disposed in a lower portion 16b, and a drive shaft
22 that transmits a driving force of the electric motor 15 to the propeller shaft
21. The propeller 20 rotated by the driving force of the electric motor 15 applies
a propulsive force to the marine vessel 10. The propeller shaft 21 is disposed along
the fore-and-aft of the marine vessel 10, and the drive shaft 22 is disposed along
the vertical direction of the marine vessel 10
[0022] A steering mechanism (not illustrated) is provided in the outboard motor 13, and
by swinging the outboard motor 13 in the crosswise direction of the marine vessel
10 with respect to the hull 11, adjusts the direction in which a propulsive force
generated by the outboard motor 13 acts with respect to the crosswise direction.
[0023] The bracket 18 is attached to the stern 12 of the hull 11 via the lift mechanism
19, wherein the lift mechanism 19 moves the bracket 18 with respect to the vertical
direction of the marine vessel 10. The outboard motor main body 16 is attached to
the bracket 18. As a result, the lift mechanism 19 moves the outboard motor main body
16 via the bracket 18 with respect to the vertical direction of the marine vessel
10.
[0024] The outboard motor main body 16 is attached to the bracket 18 rotatably about the
tilt shaft 17. The tilt shaft 17 extends in the crosswise direction of the marine
vessel 10, and hence the outboard motor main body 16 rotates about the tilt shaft
17 counterclockwise as viewed in the drawing (first rotation) such that the upper
portion 16a moves forward and downward of the marine vessel 10 and the lower portion
16b moves rearward and upward of the marine vessel 10, or rotates about the tilt shaft
17 clockwise as viewed in the drawing (second rotation) such that the upper portion
16a moves rearward and downward of the marine vessel 10 and the lower portion 16b
moves forward and upward of the marine vessel 10. Note that the first rotation will
be referred to as "tilt-up", and the second rotation will be referred to as "trim-in".
[0025] The bracket 18 comprises a rotational mechanism, such as a power tilt trim (not illustrated),
including a hydraulic actuator for tilting up the outboard motor main body 16 and
a hydraulic actuator for trimming in the outboard motor main body 16. The lift mechanism
19 includes a hydraulic actuator (not illustrated) for moving up and down the bracket
18.
[0026] While the marine vessel 10 is sailing, the lift mechanism 19 adjusts (changes) the
position of the outboard motor main body 16 with respect to the vertical direction
via the bracket 18 so that the propeller 20 can be entirely submerged under the water
surface. At this time, the distance L6 from the tilt shaft 17 to the lower end of
the stern 12 with respect to the vertical direction is equal to or shorter than the
distance L1 (first distance) from the tilt shaft 17 to the upper end of the stern
12 with respect to the vertical direction. Namely, the tilt shaft 17 is closer to
the lower end of the stern 12 than to the upper end of the stern 12 with respect to
the vertical direction. Moreover, the distance L2 (second distance) from the tilt
shaft 17 to the propeller shaft 21 with respect to the vertical direction is equal
to or shorter than the distance L1. Further, the distance L4 from the tilt shaft 17
to the lower end of the outboard motor main body 16 with respect to the vertical direction
is equal to or shorter than the distance L3 from the tilt shaft 17 to the upper end
of the outboard motor main body 16 with respect to the vertical direction. Namely,
the tilt shaft 17 is closer to the lower end of the outboard motor main body 16 than
to the upper end of the outboard motor main body 16 with respect to the vertical direction.
In addition, the distance L5 from the rear end of the stern 12 to the tilt shaft 17
with respect to the fore-and-aft direction is greater than zero. Namely, the tilt
shaft 17 is disposed at more rear than the rear end of the stern 12 with respect to
the fore-and-aft direction.
[0027] FIGS. 3A to 3C are views useful in explaining trim-in and tilt-up of the outboard
motor main body 16 in the first preferred embodiment.
[0028] As shown in FIG. 3A, while the marine vessel 10 is sailing, the outboard motor main
body 16 that has not been trimmed in or tilted up is held by the bracket 18 such that
the drive shaft 22 lies along the vertical direction. When a vessel operator or the
like instructs to trim in the outboard motor main body 16, the power tilt trim of
the bracket 18 rotates the outboard motor main body 16 clockwise as viewed in the
drawing with respect to the tilt shaft 17 (FIG. 3B).
[0029] Here, as described above, with respect to the vertical direction, the tilt shaft
17 is closer to the lower end of the stern 12 than to the upper end of the stern 12,
and the distance L2 from the tilt shaft 17 to the propeller shaft 21 with respect
to the vertical direction is equal to or shorter than the distance L1 from the tilt
shaft 17 to the upper end of the stern 12 with respect to the vertical direction.
Namely, the tilt shaft 17 is disposed closer to the bottom, and in the outboard motor
main body 16, the tilt shaft 17 is closer to the lower end of the outboard motor main
body 16 than to the upper end of the outboard motor main body 16. Thus, the distance
from the tilt shaft 17 to the lower end of the outboard motor main body 16 is short,
and hence the amount of the forward movement of the lower portion 16b of the outboard
motor main body 16 when the outboard motor main body 16 is trimmed in about the tilt
shaft 17, is small. As a result, even if the amount of trim-in is increased, the interference
of the lower portion 16b with the stern 12 can be prevented, and the outboard motor
main body 16 can be trimmed in to a great extent.
[0030] Moreover, in the present preferred embodiment, the tilt shaft 17 is disposed at more
rear than the rear end of the stern 12 with respect to the fore-and-aft direction,
as described above. In this arrangement, the outboard motor main body 16 is away from
the stern 12, which makes the lower portion 16b less likely to interfere with the
stern 12 when the outboard motor main body 16 is trimmed in about the tilt shaft 17.
Therefore, placing the tilt shaft 17 at more rear than the rear end of the stern 12
with respect to the fore-and-aft direction contributes to achieving a great trim-in
of the outboard motor main body 16.
[0031] In this way, in the present preferred embodiment, the great trim-in of the outboard
motor main body 16 can be achieved. Specifically, the position of the tilt shaft 17
while the marine vessel 10 is sailing is set such that the maximum rotational angle
θ
1 (maximum trim-in angle) is equal to or greater than 20° (θ
1 ≥ 20°), more preferably equal to or greater than 30° (θ
1 ≥ 30°), wherein at the maximum rotational angle θ
1, the lower portion 16b of the outboard motor main body 16 does not interfere with
the stern 12 of the hull 11 or the bracket 18 when the outboard motor main body 16
is rotated clockwise as viewed in the drawings with respect to the tilt shaft 17 from
the state in which the drive shaft 22 lies along the vertical direction (neutral state).
[0032] To anchor the marine vessel 10 at a pier for a long period of time for storage, the
outboard motor main body 16 is lifted out of water. In this case, the lift mechanism
19 raises the outboard motor main body 16 to its uppermost position via the bracket
18, and further, the power tilt trim of the bracket 18 tilts up the outboard motor
main body 16 with respect to the tilt shaft 17 (FIG. 3C). At this time, with the upward
movement of the bracket 18, the tilt shaft 17 is positioned closer to the upper side,
and hence even if the amount of tilt-up is increased, the upper portion 16a of the
outboard motor main body 16 can be prevented from interfering with the stern 12, by
which the great tilt-up of the outboard motor main body 16 can be achieved. As a result,
the lower portion 16b of the outboard motor main body 16 can be relatively moved upward
to a great extent, enabling the propeller 20 to reliably leave water.
[0033] FIGS. 4A to 4C are views useful in explaining shift of a state of a planing boat
equipped with an outboard motor including a conventional reciprocating engine to a
planing state.
[0034] When a conventional planing boat 40 is sailing at low speed, lift force is hardly
generated at a vessel's bottom, and hence as with a marine vessel of a displacement
type, water draft has a predetermined depth. At this time, an outboard motor 41 is
hardly trimmed in, and the loading direction (acting direction) of a propulsive force
f generated by a propeller 42 of the outboard motor 41 is parallel or substantially
parallel to the water surface (FIG. 4A). Note that in FIG. 4A to FIG. 4C, the loading
direction of the propulsive force f is indicated by dot-dashed lines, and the water
surface is indicated by a solid line.
[0035] When the vessel speed increases, a wave is generated due to cutwater of a bow 43
of the planing boat 40, a hull 44 of the planing boat 40 is raised by the wave crest,
and a stern 45 of the planing boat 40 falls into a wave hollow, causing the planing
boat 40 to be into a hump state in which the bow 43 to be raised relatively (FIG.
4B). In the hump state, the resistance, wave-making resistance, and viscous resistance
acting on the hull 44 increase, making it difficult for the vessel speed to increase,
and therefore, no lift is generated at the vessel's bottom, making it difficult for
the planing boat 40 to go into the planing state. To end the hump state, for example,
a pitching moment (a counterclockwise moment as viewed in the drawings) as to lower
the bow 43 should be generated about a center of gravity 46 of the hull 44 by the
propulsive force f.
[0036] However, the outboard motor 41 of the conventional planing boat 40 is allowed to
be trimmed in up to only about 4° about a tilt shaft 47 as described above, and the
loading direction of the propulsive force f generated by the propeller 42 provided
in a lower portion of the outboard motor 41 is kept below the center of gravity 46.
As a result, a pitching moment 48 generated about the center of gravity 46 by the
propulsive force f is a moment clockwise as viewed in the drawings and acts on the
hull 44 to raise the bow 43. Note that the pitching moment 48 is indicated by white
arrows in the drawings.
[0037] Accordingly, the conventional planing boat 40 is equipped with a trim tab 49 as a
posture control plate at the stern 45. The trim tab 49 rotates at the stern 45 with
respect to the vertical direction of the planing boat 40. In the conventional planing
boat 40, lift force L is generated in the vicinity of the bow 45 by the trim tab 49
being lowered. The lift force L generates a pitching moment 50 (a moment counterclockwise
as viewed in the drawing) as to lower the bow 43 about the center of gravity 46 (FIG.
4C). As a result, the bow is lowered, ending the hump state. As a result, the resistance
acting on the hull 44 is decreased to increase the vessel speed, and the lift force
generated at the vessel's bottom enables the planing boat 40 to go into the planing
state. Note that the pitching moment 50 is indicated by a hatched arrow in the drawing.
[0038] When the trim tab 49 is lowered, the resistance acting on the trim tab 49 increases,
and hence the reciprocating engine of the outboard motor 41 is required to have high
power output, leading to upsizing of the reciprocating engine and upsizing of the
outboard motor 41. On the other hand, in the marine vessel 10 equipped with the outboard
motor 13 using the electric motor 15 according to the present preferred embodiment,
it is unnecessary to use a trim tab so as to end the hump state. A detailed description
thereof will be given below.
[0039] FIGS. 5A to 5C are views useful in explaining a shift of a state of a marine vessel
10 equipped with the outboard motor 13 including the electric motor 15 according to
the first preferred embodiment, to the planing state.
[0040] As with the plaining boat 40, when the marine vessel 10 is sailing at low speed,
lift force is hardly generated at the vessel's bottom, and hence water draft has a
predetermined depth. At this time, the outboard motor 13 is hardly trimmed in, and
the loading direction (acting direction) of a propulsive force F generated by the
propeller 20 of the outboard motor 13 is parallel or substantially parallel to the
water surface (FIG. 5A). Note that in FIG. 5A to FIG. 5C, the loading direction of
the propulsive force F is indicated by dot-dashed lines, and the water surface is
indicated by a solid line.
[0041] When the vessel speed increases, a wave is generated due to cutwater of a bow 23
of the marine vessel 10, causing the marine vessel 10 to be into a hump state in which
the bow 23 to be raised relatively (FIG. 5B). As described above, in the outboard
motor 13, the position of the tilt shaft 17 while the marine vessel 10 is sailing
is set such that the maximum rotational angle θ
1 is equal to or greater than 20° (θ
1 ≥ 20°), and more preferably equal to or greater than 30° (θ
1 ≥ 30°). As a result, the outboard motor main body 16 can be trimmed in to a great
extent, and accordingly, the loading direction of the propulsive force F can be turned
upward to a great extent. Thus, the loading direction of the propulsive force F generated
by the propeller 20 can be shifted above a center of gravity 24, and hence a pitching
moment 25 generated about the center of gravity 24 by the propulsive force F is counterclockwise
as viewed in the drawing and acts on the hull 11 to lower the bow 23 (FIG. 5C). Note
that the pitching moment 25 is indicated by a white arrow in the drawing.
[0042] That is, in the present preferred embodiment, the outboard motor main body 16 can
be trimmed in to a great extent, and the propulsive force F can therefore generate
the pitching moment 25 for lowering the bow 23. As a result, it can eliminate a necessity
of use a trim tab for the purpose of ending the hump state, and therefore eliminate
the necessity of a trim tab to be placed in the marine vessel 10. Moreover, required
output of the electric motor 15 can be reduced, and upsizing of the electric motor
15 can be avoided.
[0043] A description will now be given of a second preferred embodiment. The second preferred
embodiment differs from the first preferred embodiment in that a marine vessel 60
is a hydrofoil boat, not a planing boat. The other configurations and operations are
basically the same as those of the first preferred embodiment described above, and
hence the corresponding configurations and operations will not be described.
[0044] FIG. 6 is a side view of a marine vessel 60 to which an outboard motor 13 according
to the second preferred embodiment is applied. FIG. 7 is a side view useful in explaining
the outline of a configuration of the outboard motor 13 according to the second preferred
embodiment.
[0045] The marine vessel 60 is a hydrofoil, and includes a hull 61 and at least one, for
example, two outboard motors 13 as marine propulsion devices to be attached to a stern
62 of the hull 61. A cabin 63 also serving as a cockpit is disposed in the hull 61.
FIG. 6 shows the marine vessel 60 in a foilborne sailing state, but the marine vessel
60 is not limited to the hydrofoil, and may be, for example, a relatively small marine
vessel of a displacement type equipped with hydrovanes.
[0046] The marine vessel 60 further has hydrovanes 64. The hydrovanes 64 may be configured
to be accommodatable into the hull 61. The number of hydrovanes 64 is not limited;
however, it is preferred that at least two hydrovanes 64 are disposed side by side
in the fore-and-aft direction of the marine vessel 60. When the speed of the marine
vessel 60 increases, lift force generated by the hydrovanes 64 increases, causing
the hull 61 to leave water and causing the marine vessel 60 to go into the foilborne
sailing state.
[0047] Note that in the drawings to be referred to below, the left side in the figures corresponds
to a forward direction of the marine vessel 60, the right side in the figures corresponds
to a rearward direction of the marine vessel 60, the upper side in the figures corresponds
to an upper direction of the marine vessel 60, and the lower side in the figures corresponds
to a lower direction of the marine vessel 60, a depth direction in the figures corresponds
to a right direction of the marine vessel 60, and a front direction in the figures
corresponds to a left direction of the marine vessel 60.
[0048] As with the first preferred embodiment, while the marine vessel 60 is foilborne-sailing,
the lift mechanism 19 of the outboard motor 13 adjusts the position of the outboard
motor main body 16 with respect to the vertical direction via the bracket 18 so that
the propeller 20 can be entirely submerged under the water surface. The bottom of
the marine vessel 60 while foilborne-sailing entirely floats over the water surface
as shown in FIG. 6, which requires the lift mechanism 19 to move the propeller 20
downward to a lower position than the outboard motor 13 (the first preferred embodiment)
provided in the marine vessel 10, which is a planing boat.
[0049] Specifically, in order to move the propeller 20 downward, the lift mechanism 19 moves
the outboard motor main body 16 downward to a lower position, than the position of
the outboard motor main body 16 while the marine vessel 10 is sailing (the first preferred
embodiment). Thus, in the second preferred embodiment, as distinct from the first
preferred embodiment, the tilt shaft 17 of the bracket 18 lies at a lower position
than the lower end of the stern 62, wherein the distance L6 from the lower end of
the stern 62 to the tilt shaft 17 with respect to the vertical direction is equal
to or shorter than the distance L1 from the upper end of the stern 62 to the tilt
shaft 17. In other words, also in the second preferred embodiment, the tilt shaft
17 is closer to the lower end of the stern 62 than to the upper end of the stern 62
with respect to the vertical direction. Moreover, the distance L2 from the tilt shaft
17 to the propeller shaft 21 with respect to the vertical direction is equal to or
shorter than the distance L1. Specifically, the distance L1 is twice or more as long
as the distance L2. Note that in the first preferred embodiment and the second preferred
embodiment, the outboard motor 13 has the same structure, and hence as with the first
preferred embodiment, the distance L4 from the tilt shaft 17 to the lower end of the
outboard motor main body 16 with respect to the vertical direction is equal to or
shorter than the distance L3 from the tilt shaft 17 to the upper end of the outboard
motor main body 16 with respect to the vertical direction. Namely, also in the second
preferred embodiment, the tilt shaft 17 is positioned closer to the bottom. Further,
the distance L5 from the rear end of the stern 62 to the tilt shaft 17 with respect
to the fore-and-aft direction is greater than zero, as with the first preferred embodiment.
[0050] FIGS. 8A to 8C are views useful in explaining trim-in and tilt-up of the outboard
motor main body 16 in the second preferred embodiment.
[0051] As shown in FIG.8A, while the marine vessel 60 is foilborne-sailing, the outboard
motor main body 16 that has not been trimmed in or tilted up is held by the bracket
18 such that the drive shaft 22 lies along the vertical direction. When a vessel operator
or the like instructs to trim in the outboard motor main body 16, the power tilt trim
of the bracket 18 rotates the outboard motor main body 16 clockwise as viewed in the
drawing with respect to the tilt shaft 17 (FIG. 8B).
[0052] As described above, also in the second preferred embodiment, the tilt shaft 17 is
disposed closer to the bottom, and the tilt shaft 17 is closer to the lower end of
the outboard motor main body 16 than to the upper end of the outboard motor main body
16. Thus, the amount of the forward movement of the lower portion 16b of the outboard
motor main body 16 when the outboard motor main body 16 is trimmed in about the tilt
shaft 17, is small. As a result, as with the first preferred embodiment, the outboard
motor main body 16 can be trimmed in to a great extent. Also in the second embodiment,
the position of the tilt shaft 17 while the marine vessel 60 is foilborne-sailing
is set such that the maximum trim-in angle θ
1 is equal to or greater than 20° (θ
1 ≥ 20°), more preferably equal to or greater than 30° (θ
1 ≥ 30°). Note that in the second preferred embodiment, the tilt shaft 17 is moved
to a lower position than in the first preferred embodiment, and hence in the second
preferred embodiment, the lower portion 16b of the outboard motor main body 16 gets
further away from the stern 62 of the hull 61. In the second preferred embodiment,
the lower portion 16b of the outboard motor main body 16 is further away from the
stern 62 than in the first preferred embodiment, and hence the outboard motor main
body 16 can be trimmed in to a greater extent. Accordingly, in the second preferred
embodiment, the maximum trim-in angle θ
1 may be set to a greater value than the maximum trim-in angle θ
1 in the first preferred embodiment.
[0053] Note that as with the first preferred embodiment, to anchor the marine vessel 60
at a pier for a long period of time, the lift mechanism 19 raises the outboard motor
main body 16 to its uppermost position, and also tilts up the outboard motor main
body 16 with respect to the tilt shaft 17 (FIG. 8C).
[0054] As an alternative with regard to the embodiment, the outboard motor 13 may be equipped
with any of the following in place of an electric motor as a power source: an internal
combustion engine in which lubricating oil never goes back to a crankcase and burns
even if the outboard motor main body 16 is trimmed in to a great extent, such as a
rotary engine and a reciprocating engine disposed such that its cylinder head is never
positioned below a cylinder block when the outboard motor main body 16 is trimmed
in.
1. An outboard motor (13) configured to be attached to a marine vessel (10, 60) having
a hull (11, 61) with a stern (12, 62), comprising:
a main body (16) that incorporates a power source (15) therein; and
a bracket (18) that includes a rotating shaft (17), wherein the bracket (18) is configured
to be attached to the stern (12, 62), wherein
the main body (16) is attached to the bracket (18) so as to be able to rotate a first
rotation and a second rotation about the rotation shaft (17),
a propeller shaft (21) for rotating a propeller (20) is provided at a lower portion
(16b) of the main body (16),
in the first rotation, the main body (16) rotates about the rotating shaft (17) such
that an upper portion (16a) of the main body (16) with regard to a vertical direction
of the marine vessel (10, 60) moves toward the stern (12, 62) of the marine vessel
(10, 60) and a lower portion (16b) of the main body (16) with regard to a vertical
direction of the marine vessel (10, 60) moves away from the stern (12, 62) of the
marine vessel (10, 60),
in the second rotation, the main body (16) rotates about the rotating shaft (17) such
that the upper portion (16a) of the main body (16) moves away from the stern (12,
62) of the marine vessel (10, 60) and the lower portion (16b) of the main body (16)
moves toward the stern (12, 62) of the marine vessel (10, 60), and
while the marine vessel (10, 60) is sailing, a first distance (L1) from the rotating
shaft (17) to an upper end of the stern (12, 62) with respect to a vertical direction
of the marine vessel (10, 60) is equal to or longer than a second distance (L2) from
the rotating shaft (17) to the propeller shaft (21) with respect to the vertical direction
of the marine vessel (10, 60).
2. The outboard motor (13) according to claim 1, wherein while the marine vessel (10,
60) is sailing, the first distance (L1) is twice or more as long as the second distance
(L2).
3. The outboard motor (13) according to claim 1 or 2, wherein with respect to a fore-and-aft
direction of the hull (11, 61), the rotating shaft (17) is disposed at more rear than
a rear end of the stern (12, 62).
4. The outboard motor (13) according to at least one of the claims 1 to 3, wherein in
the second rotation, the main body (16) rotates about the rotating shaft (17) by a
rotation angle of 20° or more.
5. The outboard motor (13) according to at least one of the claims 1 to 4, wherein in
the second rotation, the main body (16) rotates about the rotating shaft (17) by a
rotation angle of 30° or more.
6. The outboard motor (13) according to at least one of the claims 1 to 5, wherein a
posture control plate that rotates with respect the vertical direction of the marine
vessel (10, 60) is not disposed at the stern (12, 62) of the hull (11, 61).
7. The outboard motor (13) according to at least one of the claims 1 to 6, further comprising
a lift mechanism (19) that is configured to move the main body (16) with respect to
the vertical direction of the marine vessel (10, 60).
8. The outboard motor (13) according to claim 7, wherein the lift mechanism (19) is configured
for changing a position of the main body (16) with respect to the vertical direction
of the marine vessel (60) while the marine vessel (60) is sailing.
9. The outboard motor (13) according to claim 7 or 8, wherein the marine vessel (60)
comprises hydrovanes (64), and the lift mechanism (19) is configured to move the main
body (16) downward to a lower side of the hull (11, 61) while the marine vessel (60)
is foilborne-sailing.
10. The outboard motor (13) according to at least one of the claims 7 to 9, wherein the
lift mechanism (19) is configured to raise the main body (16), and the main body (16)
rotates the first rotation.
11. The outboard motor (13) according to at least one of the claims claim 1 to 10, wherein
the power source is an electric motor (15).
12. An outboard motor (13) configured to be attached to a marine vessel (10, 60) having
a hull (11, 61) with a stern (12, 62), comprising:
a main body (16) that incorporates a power source (15) therein; and
a bracket (18) that includes a rotating shaft (17), wherein the bracket (18) is configured
to be attached to the stern (12, 62), wherein
the main body (16) is attached to the bracket (18) so as to be able to rotate a first
rotation and a second rotation about the rotation shaft (17),
in the first rotation, the main body (16) rotates about the rotating shaft (17) such
that an upper portion (16a) of the main body (16) with regard to a vertical direction
of the marine vessel (10, 60) moves toward the stern (12, 62) of the marine vessel
(10, 60) and a lower portion (16b) of the main body (16) with regard to a vertical
direction of the marine vessel (10, 60) moves away from the stern (12, 62) of the
marine vessel (10, 60),
in the second rotation, the main body (16) rotates about the rotating shaft (17) such
that the upper portion (16a) of the main body (16) moves away from the stern (12,
62) of the marine vessel (10, 60) and the lower portion (16b) of the main body (16)
moves toward the stern (12, 62) of the marine vessel (10, 60), and
with respect to the vertical direction of the marine vessel (10, 60), the rotating
shaft (17) is disposed closer to a lower end of the stern (12, 62) than to an upper
end of the stern (12, 62).
13. An outboard motor (13) configured to be attached to a marine vessel (10, 60) having
a hull (11, 61) with a stern (12, 62), comprising:
a main body (16) that incorporates a power source (15) therein; and
a bracket (18) that includes a rotating shaft (17), wherein the bracket (18) is configured
to be attached to the stern (12, 62), wherein
the main body (16) is attached to the bracket (18) so as to be able to rotate a first
rotation and a second rotation,
in the first rotation, the main body (16) rotates about the rotating shaft (17) such
that an upper portion (16a) of the main body (16) with regard to a vertical direction
of the marine vessel (10, 60) moves toward the stern (12, 62) of the marine vessel
(10, 60) and a lower portion (16b) of the main body (16) with regard to a vertical
direction of the marine vessel (10, 60) moves away from the stern (12, 62) of the
marine vessel (10, 60),
in the second rotation, the main body (16) rotates about the rotating shaft (17) such
that the upper portion (16a) of the main body (16) moves away from the stern (12,
62) of the marine vessel (10, 60) and the lower portion (16b) of the main body (16)
moves toward the stern (12, 62) of the marine vessel (10, 60), and
with respect to the vertical direction of the marine vessel (10, 60), the rotating
shaft (17) is disposed closer to a lower end of the main body (16) than to an upper
end of the main body (16).
14. A marine vessel (10, 60) equipped with an outboard motor (13) according to at least
one of the claims 1 to 13.