This application claims the benefit of priority to Japanese Patent Application No. 2019-236264 filed on Dec. 26, 2019. The entire contents of this application are hereby incorporated herein by reference.
The present invention relates to a marine propulsion unit and a marine vessel.
A marine propulsion unit is known in general. Such a marine propulsion unit is disclosed in International Publication No. 2017/082248, for example.
International Publication No. 2017/082248 discloses a marine propulsion unit including a power supply wire to supply power, a signal wire to transmit a predetermined signal, and a hollow steering shaft to steerably support a duct. The power supply wire and the signal wire are introduced into a marine propulsion unit main body by being directly inserted into the steering shaft from an upper end of the hollow steering shaft.
In the marine propulsion unit disclosed in International Publication No. 2017/082248, the power supply wire and the signal wire are directly inserted into the steering shaft. Thus, when the duct is steered about the steering shaft, it is necessary to prevent action of relatively large torsional and bending stresses on the power supply wire and the signal wire, and the steering angle of the duct is constrained.
Preferred embodiments of the present invention provide marine propulsion units and marine vessels that each significantly reduce or prevent constraints on the steering angles of ducts.
A marine propulsion unit according to a preferred embodiment of the present invention includes a duct including a stator, a propeller including a rim including a rotor that faces the stator, and a blade provided radially inwardly of the rim, a steering shaft that extends in an upward-downward direction so as to rotatably support the duct, a casing rotated by the steering shaft and provided above the duct so as to house the steering shaft and a controller configured or programmed to control driving of the propeller, a power supply wire to supply power from a power source to the stator, and a signal wire to transmit a drive signal to the controller. The power supply wire and the signal wire are located outside and along the casing so as to pass in front of the steering shaft along a rotation direction of the steering shaft from a first side of the casing to a second side of the casing in a right-left direction in a plan view.
In a marine propulsion unit according to a preferred embodiment of the present invention, the power supply wire and the signal wire are located outside and along the casing so as to pass in front of the steering shaft along the rotation (steering) direction of the steering shaft from the first side of the casing to the second side of the casing in the right-left direction in the plan view. Accordingly, the power supply wire and the signal wire are located so as to be wound around the steering shaft in an arcuate shape having a relatively small curvature (an arcuate shape having a large radius) along the casing. Furthermore, the power supply wire and the signal wire are located along the rotation direction of the steering shaft such that when the duct is steered about the steering shaft, the duct is steered while a state in which the power supply wire and the signal wire are wound in an arcuate shape having a relatively small curvature (an arcuate shape having a large radius) along the casing is maintained. Therefore, large torsion (deformation) of the power supply wire and the signal wire is significantly reduced or prevented during steering of the duct, and thus a constraint on the steering angle of the duct is significantly reduced or prevented. Furthermore, the power supply wire and the signal wire are located along the casing such that spaces to provide the power supply wire and the signal wire are relatively reduced.
In a marine propulsion unit according to a preferred embodiment of the present invention, the power supply wire and the signal wire are preferably located along the casing so as to pass in front of the casing. Accordingly, using the front surface of the casing, the power supply wire and the signal wire are easily located so as to be wound around the steering shaft in an arcuate shape having a relatively small curvature along the casing.
In a marine propulsion unit according to a preferred embodiment of the present invention, the power supply wire and the signal wire preferably include first portions on the first side in the right-left direction, and second portions introduced into the casing on the second side in the right-left direction. Accordingly, as compared with a case in which the power supply wire and the signal wire are located on only one side in the right-left direction, the power supply wire and the signal wire have a larger arcuate shape (longer path length). Therefore, when the duct is steered about the steering shaft, the duct is steered while a state in which the power supply wire and the signal wire are wound in an arcuate shape having a relatively small curvature (an arcuate shape having a large radius) along the casing in a larger range is maintained. Consequently, large torsion (deformation) of the power supply wire and the signal wire is further significantly reduced or prevented during steering of the duct, and thus a constraint on the steering angle of the duct is further significantly reduced or prevented.
In such a case, the casing preferably includes, on the second side in the right-left direction, an introduction hole to allow the second portions to be introduced into the casing therethrough, and the second portions are preferably introduced into the introduction hole obliquely from a lower front side toward an upper rear side, as viewed in the right-left direction. Accordingly, the power supply wire and the signal wire that hang down due to gravity are introduced from below, and thus action of large torsional and bending stresses on the power supply wire and the signal wire is further significantly reduced or prevented.
In a marine propulsion unit according to a preferred embodiment of the present invention, the power supply wire is preferably more vulnerable to torsion and easier to bend than the signal wire, and the signal wire is preferably harder to bend and more resistant to torsion than the power supply wire. Accordingly, even when the power supply wire that is relatively vulnerable to torsion and the signal wire that is relatively hard to bend are used, action of large torsional and bending stresses on the power supply wire and the signal wire is significantly reduced or prevented. Therefore, the steerable marine propulsion unit is reliably wired.
In a marine propulsion unit according to a preferred embodiment of the present invention, the casing preferably includes a curved surface that protrudes forward in a plan view, and the power supply wire and the signal wire are preferably curved along the curved surface. Accordingly, the power supply wire and the signal wire are located along the curved surface, and thus when the duct is steered about the steering shaft, the duct is steered while a state in which the power supply wire and the signal wire are curved more smoothly and are wound in an arcuate shape having a relatively small curvature (an arcuate shape having a large radius) along the casing is maintained. Therefore, large torsion (deformation) of the power supply wire and the signal wire is further significantly reduced or prevented during steering of the duct. Thus, action of large torsional and bending stresses on the power supply wire and the signal wire is further significantly reduced or prevented, and thus a constraint on the steering angle of the duct is further significantly reduced or prevented.
In such a case, the curved surface preferably has a substantially arcuate shape that protrudes forward in the plan view, and the power supply wire and the signal wire are preferably placed in a substantially elliptical shape along the curved surface having the substantially arcuate shape. Note that the substantially arcuate shape includes a precise arcuate shape and shapes similar to the arcuate shape. Furthermore, the substantially elliptical shape includes a precise elliptical shape and shapes similar to the elliptical shape. Accordingly, the power supply wire and the signal wire are easily placed in a substantially elliptical shape along the curved surface, and thus the power supply wire and the signal wire are placed along the casing in a larger range as compared with a case in which the power supply wire and the signal wire are placed in a circular shape. Therefore, action of large torsional and bending stresses on the power supply wire and the signal wire is further significantly reduced or prevented.
In a marine propulsion unit according to a preferred embodiment of the present invention, the casing preferably has a streamlined shape with a rotation axis direction of the propeller as a longitudinal direction, and the power supply wire and the signal wire are preferably located along the casing having the streamlined shape such that lower ends thereof are submerged in water. Accordingly, using up to a region in which the power supply wire and the signal wire are submerged in water as spaces to provide the power supply wire and the signal wire, the power supply wire and the signal wire are located along the casing, and thus entanglement of foreign matter with the power supply wire and the signal wire is significantly reduced or prevented.
In a marine propulsion unit according to a preferred embodiment of the present invention, the power supply wire and the signal wire preferably include lower ends above the duct. Accordingly, obstruction of the power supply wire and the signal wire to the flow of water generated by the propeller installed in the duct is prevented.
In a marine propulsion unit according to a preferred embodiment of the present invention, the power supply wire and the signal wire are preferably located along the casing while being inclined so as to be located more forward toward a lower side. Accordingly, the power supply wire and the signal wire are located along the casing in a larger range as compared with a case in which the power supply wire and the signal wire are located only in a substantially horizontal direction or a substantially vertical direction. Therefore, action of large torsional and bending stresses on the power supply wire and the signal wire is further significantly reduced or prevented.
In a marine propulsion unit according to a preferred embodiment of the present invention, the casing preferably includes, on the second side in the right-left direction, an introduction hole to allow the power supply wire and the signal wire to be introduced into the casing therethrough, the marine propulsion unit preferably further includes, above the casing, a cowling to allow the power supply wire and the signal wire to pass therethrough, and the cowling preferably includes, on a side opposite to the introduction hole in the right-left direction, a lead-out port to lead the power supply wire and the signal wire from within the cowling to the first side of the casing in the right-left direction. Accordingly, the power supply wire and the signal wire are led downward from the lead-out port located on the side opposite to the introduction hole in the right-left direction and above the introduction hole, and thus the power supply wire and the signal wire are easily placed along the casing while hanging down due to gravity.
In such a case, the lead-out port preferably has an elongated shape that extends in a forward-rearward direction, and the power supply wire and the signal wire are preferably moved in the forward-rearward direction inside the lead-out port along the lead-out port as the casing is rotated. Accordingly, as compared with a case in which the power supply wire and the signal wire are completely constrained by the lead-out port, torsional and bending stresses applied to the power supply wire and the signal wire during steering of the duct are reduced, and a constraint on the steering angle of the duct is further significantly reduced or prevented.
A marine propulsion unit according to a preferred embodiment of the present invention preferably further includes a restrainer to bundle the power supply wire and the signal wire at a predetermined position inside the cowling and allow the power supply wire and the signal wire to pass through the predetermined position. Accordingly, the power supply wire and the signal wire are constrained at a position spaced relatively apart from the casing to be steered. That is, the power supply wire and the signal wire are constrained at a position at which the influence of steering is relatively small. Therefore, action of large torsional and bending stresses on the power supply wire and the signal wire is further significantly reduced or prevented.
In such a case, a marine propulsion unit according to a preferred embodiment of the present invention preferably further includes a trim-tilt mechanism to rotate a marine propulsion unit main body in the upward-downward direction, and the restrainer is preferably freely rotatable about an axis that extends in the right-left direction when the marine propulsion unit main body is rotated in the upward-downward direction by the trim-tilt mechanism. Accordingly, when the marine propulsion unit main body is rotated in the upward-downward direction by the trim-tilt mechanism, the restrainer is rotated to reduce torsional and bending stresses applied to the power supply wire and the signal wire.
A marine propulsion unit according to a preferred embodiment of the present invention preferably further includes a trim-tilt shaft, and the predetermined position is preferably located closer to the casing than the trim-tilt shaft. Accordingly, the power supply wire and the signal wire are constrained at a position spaced apart by an appropriate distance not too far from the casing. Thus, large movement of the power supply wire and the signal wire located along the casing is prevented during steering of the duct.
A marine vessel according to a preferred embodiment of the present invention includes a hull and a marine propulsion unit on the hull. The marine propulsion unit includes a duct including a stator, a propeller including a rim including a rotor that faces the stator, and a blade provided radially inwardly of the rim, a steering shaft that extends in an upward-downward direction so as to rotatably support the duct, a casing rotated by the steering shaft and provided above the duct so as to house the steering shaft and a controller configured or programmed to control driving of the propeller, a power supply wire to supply power from a power source to the stator, and a signal wire to transmit a drive signal to the controller. The power supply wire and the signal wire are located outside and along the casing so as to pass in front of the steering shaft along a rotation direction of the steering shaft from a first side of the casing to a second side of the casing in a right-left direction in a plan view.
In a marine vessel according to a preferred embodiment of the present invention, the power supply wire and the signal wire are located outside and along the casing so as to pass in front of the steering shaft along the rotation (steering) direction of the steering shaft from the first side of the casing to the second side of the casing in the right-left direction in the plan view. Thus, a constraint on the steering angle of the duct is significantly reduced or prevented, similarly to the marine propulsion unit according to preferred embodiments of the present invention described above.
In such a case, the power supply wire and the signal wire are preferably located along the casing so as to pass in front of the casing. Accordingly, using the front surface of the casing, the power supply wire and the signal wire are easily located so as to be wound around the steering shaft in an arcuate shape having a relatively small curvature along the casing.
In a marine vessel according to a preferred embodiment of the present invention, the power supply wire and the signal wire preferably include first portions on the first side in the right-left direction, and second portions introduced into the casing on the second side in the right-left direction. Accordingly, as compared with a case in which the power supply wire and the signal wire are located on only one side in the right-left direction, the power supply wire and the signal wire have a larger arcuate shape (longer path length). Therefore, when the duct is steered about the steering shaft, the duct is steered while a state in which the power supply wire and the signal wire are wound in an arcuate shape having a relatively small curvature (an arcuate shape having a large radius) along the casing in a larger range is maintained. Consequently, large torsion (deformation) of the power supply wire and the signal wire is further significantly reduced or prevented during steering of the duct, and thus a constraint on the steering angle of the duct is further significantly reduced or prevented.
In such a case, the casing preferably includes, on the second side in the right-left direction, an introduction hole to allow the second portions to be introduced into the casing therethrough, and the second portions are preferably introduced into the introduction hole obliquely from a lower front side toward an upper rear side, as viewed in the right-left direction. Accordingly, the power supply wire and the signal wire that hang down due to gravity are introduced from below, and thus action of large torsional and bending stresses on the power supply wire and the signal wire is further significantly reduced or prevented.
In a marine vessel according to a preferred embodiment of the present invention, the power supply wire is preferably more vulnerable to torsion and easier to bend than the signal wire, and the signal wire is preferably harder to bend and more resistant to torsion than the power supply wire. Accordingly, even when the power supply wire that is relatively vulnerable to torsion and the signal wire that is relatively hard to bend are used, action of large torsional and bending stresses on the power supply wire and the signal wire is significantly reduced or prevented. Therefore, the steerable marine propulsion unit is reliably wired.
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.
Preferred embodiments of the present invention are hereinafter described with reference to the drawings.
The structure of a marine vessel 101 including a marine propulsion unit 100 according to preferred embodiments of the present invention is now described with reference to
As shown in
The hull 101a includes a power source P (battery) to supply power to the marine propulsion unit 100 via power supply wires 90, and an operator S to transmit various drive signals (control signals) to the marine propulsion unit 100 via a signal wire 91. The operator S includes a remote control and a steering wheel, for example, operated by a user.
The marine propulsion unit 100 is installed at the stern (transom) of the hull 101a. The marine propulsion unit 100 is driven by power supplied from the power source P via the power supply wires 90. The marine propulsion unit 100 is driven based on a drive signal transmitted from the operator S via the signal wire 91. That is, the marine propulsion unit 100 rotates and steers a propeller 4 (duct 3) based on the drive signal transmitted from the operator S via the signal wire 91, for example.
The marine propulsion unit 100 includes an electric propulsion device to propel the marine vessel 101 (hull 101a). The marine propulsion unit 100 includes a bracket B, a trim-tilt mechanism 1, a restrainer 2, the duct 3 including a stator 30, the propeller 4 including a rim 40 and blades 41, a steering shaft 5, a steering 6, a casing 7, a cowling 8, the power supply wires 90, and the signal wire 91. The structure of each portion of the marine propulsion unit 100 is now sequentially described.
The bracket B supports a marine propulsion unit main body 100a. The marine propulsion unit main body 100a refers to an entire structure (excluding the bracket B) rotated about a trim-tilt shaft B30 by the trim-tilt mechanism 1.
The bracket B includes a fixed bracket B10 and a movable bracket B20.
The fixed bracket B10 is fixed to the stern. The fixed bracket B10 includes the trim-tilt shaft B30 that extends in the right-left direction. The movable bracket B20 directly supports the marine propulsion unit main body 100a. The movable bracket B20 rotates in an upward-downward direction about the trim-tilt shaft B30 together with the marine propulsion unit main body 100a.
The fixed bracket B10 includes a shaft B11 that extends in the right-left direction. The shaft B11 rotatably supports a lower end of the trim-tilt mechanism 1 (cylinder).
The movable bracket B20 includes a shaft B21 that extends in the right-left direction. The shaft B21 is rotatably supported by an upper end of the trim-tilt mechanism 1 (cylinder). The shaft B21 is directly pushed up by extension of the trim-tilt mechanism 1, and is directly pushed down by contraction of the trim-tilt mechanism 1. When the shaft B21 is directly pushed up by the trim-tilt mechanism 1, the marine propulsion unit main body 100a is rotated upward. When the shaft B21 is directly pushed down by the trim-tilt mechanism 1, the marine propulsion unit main body 100a is rotated downward.
The trim-tilt mechanism 1 rotates the marine propulsion unit main body 100a in the upward-downward direction. The trim-tilt mechanism 1 includes a tubular cylinder including an expandable and contractable rod.
The upper end of the trim-tilt mechanism 1 rotatably supports the shaft B21, as described above. The restrainer 2 is rotatably installed on the shaft B21 side by side with the upper end of the trim-tilt mechanism 1. That is, the upper end of the trim-tilt mechanism 1 and the restrainer 2 are located adjacent to each other in the right-left direction (see
The shaft B21 is located rearward of the trim-tilt shaft B30. That is, the shaft B21 is positioned closer to the casing 7 than the trim-tilt shaft B30 in a forward-rearward direction. Therefore, the restrainer 2 is positioned closer to the casing 7 than the trim-tilt mechanism 1 in the forward-rearward direction. The shaft B21 (the restrainer 2 and the upper end of the trim-tilt mechanism 1) is located inside the cowling 8.
As shown in
The cylindrical portion 20 (restrainer 2) is rotatable with respect to the shaft B21. The restraining portion 21 includes a through-hole, and the power supply wires 90 and the signal wire 91 are bundled by passing through the through-hole. Therefore, the restrainer 2 bundles the power supply wires 90 and the signal wire 91 at a predetermined position inside the cowling 8 and allows the power supply wires 90 and the signal wire 91 to pass through the predetermined position. The predetermined position refers to the vicinity of the shaft B21. That is, the predetermined position is located closer to the casing 7 than the trim-tilt shaft B30. The restraining portion 21 is located above the cylindrical portion 20, and allows the power supply wires 90 and the signal wire 91 to pass therethrough above the cylindrical portion 20.
As described above, the shaft B21 is inserted through the restrainer 2, and the restrainer 2 is rotatable with respect to the shaft B21. That is, the restrainer 2 is freely rotatable about an axis (shaft B21) that extends in the right-left direction when the marine propulsion unit main body 100a is rotated by the trim-tilt mechanism 1.
If the restrainer 2 were fixed to the shaft B21, rear portions (portions rearward of the restrainer 2) of the power supply wires 90 and the signal wires 91 would be moved upward (downward) together with the restrainer 2 when the shaft B21 moves (rotates) upward (downward) about the trim-tilt shaft B30. Consequently, the power supply wires 90 and the signal wire 91 receive a large bending stress inside the cowling 8, and it is not preferable.
As shown in
The stator 30 includes a cylindrical and annular winding that surrounds the propeller 4, and power is supplied to the winding such that a magnetic field is generated. The magnetic force of the stator 30 acts on the rotor 40a such that the propeller 4 is rotated. That is, the stator 30 of the duct 3 and the rotor 40a of the propeller 4 define an electric motor.
The rim 40 of the propeller 4 has a tubular shape and is located outside the blades 41. Furthermore, the rim 40 faces the stator 30 from the inside. The blades 41 are positioned radially inwardly of the rim 40 from the inner peripheral surface of the rim 40. The rotor 40a and the stator 30 face each other at a predetermined interval in the radial direction of the duct 3.
The steering shaft 5 extends in the upward-downward direction and supports the duct 3 such that the duct 3 is rotatable (steerable) in the right-left direction. Specifically, the steering shaft 5 is rotatably supported by the steering 6 via a bearing (not shown). Furthermore, the steering shaft 5 supports, via a bearing (not shown), the casing 7 that is Integral and unitary with the duct 3. The steering shaft 5 is located (inserted) inside the steering 6 and the casing 7 in the order of the steering 6 and the casing 7 from the upper side to the lower side.
As shown in
The housing 60 is hollow and watertight. The housing 60 is fixed to a bottom plate 80 (see
The electric motor 61 rotates the worm gear 62. The worm gear 62 contacts the steering shaft 5, and transmits the driving force of the electric motor 61 to the steering shaft 5 to rotate (steer) the steering shaft 5.
The casing 7 shown in
The casing 7 includes an introduction hole 73 through which second portions 92b described below, which are portions of the power supply wires 90 and the signal wire 91 located on the left side of the casing 7, are inserted into the casing 7. The introduction hole 73 is provided on the second side (left side) of the casing 7 in the right-left direction. In the introduction hole 73, a grommet G that keeps the inside of the casing 7 watertight is installed.
The casing 7 has a streamlined shape (fin shape) with the rotation axis direction of the propeller 4 as a longitudinal direction (see
The casing 7 includes a curved surface 72 that protrudes forward in a plan view (see
The cowling 8 is located above the casing 7 and the steering 6. The cowling 8 is an external component that covers a portion of the marine propulsion unit main body 100a above the steering 6. The power supply wires 90 and the signal wire 91 are introduced from the hull 101a into the cowling 8, and pass through the cowling 8. As described above, the restrainer 2 (predetermined position) is located inside the cowling 8. That is, the power supply wires 90 and the signal wire 91 are bundled inside the cowling 8.
The cowling 8 includes the bottom plate 80 that extends in a horizontal direction above the steering 6, and a cowling main body 81 (cover) on the bottom plate 80 from above. The cowling main body 81 is a member that covers various components such as the power supply wires 90 and the signal wire 91 to significantly reduce or prevent exposure thereof.
The cowling 8 (bottom plate 80) includes a lead-out port 80a on a side (right side) opposite to the introduction hole 73 of the casing 7 in the right-left direction. The lead-out port 80a leads the power supply wires 90 and the signal wire 91 from within the cowling 8 to the first side (right side) of the casing 7 in the right-left direction. The lead-out port 80a includes a notch at a right end of the bottom plate 80. The lead-out port 80a may include a through-hole at the right end of the bottom plate 80.
The lead-out port 80a has an elongated shape that extends in the forward-rearward direction (see
The expression “the power supply wires 90 and the signal wire 91 that pass through the lead-out port 80a are movable in the forward-rearward direction” indicates that the power supply wires 90 and the signal wire 91 are movable when the casing 7 (duct 3) is rotated by the steering 6. Specifically, as shown in
The lead-out port 80a of the cowling 8 may include a low-friction surface (not shown). The low-friction surface includes a function of preventing damage of the power supply wires 90 and the signal wire 91 due to contact (rubbing) of the power supply wires 90 and the signal wire 91 with the inner surface of the lead-out port 80a when the power supply wires 90 and the signal wire 91 that pass through the lead-out port 80a are moved in the forward-rearward direction due to steering of the duct 3. The low-friction surface may include a coating applied to the inner surface of the lead-out port 80a, or a friction reducing member that defines the inner surface of the lead-out port 80a, for example. As an example, the low-friction surface may be made of a POM resin.
If the power supply wires 90 and the signal wire 91 were restrained (not moved) in the lead-out port 80a of the cowling 8, the power supply wires 90 and the signal wire 91 would receive a large bending stress at the time of steering the duct 3, and it is not preferable.
As shown in
The signal wire 91 transmits a drive signal from the operator S mounted on the hull 101a to the controller 70, for example, in the casing 7. The signal wire 91 is harder to bend and more resistant to torsion than the power supply wires 90. The signal wire 91 includes one wire. As an example, the signal wire 91 includes a cabtyre cable.
The power supply wires 90 and the signal wire 91 are located outside and along the casing 7 so as to pass in front of the steering shaft 5 along the rotation direction of the steering shaft 5 from the first side (right side) of the casing 7 to the second side (left side) of the casing 7 in the right-left direction (see
The power supply wires 90 and the signal wire 91 are introduced from the hull 101a into the cowling 8, pass above the trim-tilt shaft B30, and are led out of the cowling 8 from the lead-out port 80a of the cowling 8 (bottom plate 80) via the restrainer 2 (predetermined position) that restrains the power supply wires 90 and the signal wire 91. The power supply wires 90 and the signal wire 91 led out of the cowling 8 from the lead-out port 80a are located outside (below) the cowling 8 and along the casing 7 so as to pass in front of the casing 7.
Specifically, the power supply wires 90 and the signal wire 91 are curved along the curved surface 72 on the front side of the casing 7. Furthermore, the power supply wires 90 and the signal wire 91 are placed in a substantially elliptical shape along the substantially arcuate curved surface 72.
As shown in
The power supply wires 90 and the signal wire 91 are located along the casing 7 while being inclined so as to be located more forward toward the lower side. That is, the power supply wires 90 and the signal wire 91 are obliquely inclined such that the forward portions thereof are lowered, as viewed in the right-left direction.
The second portions 92b of the power supply wires 90 and the signal wire 91 are introduced into the introduction hole 73 of the casing 7 obliquely from the lower front side toward the upper rear side, as viewed in the right-left direction (from the left). That is, the power supply wires 90 and the signal wire 91 are introduced into the introduction hole 73 while maintaining the wiring directions thereof along the casing 7 so as to not receive a large bending stress in the introduction hole 73.
The power supply wires 90 and the signal wire 91 are located along the streamlined casing 7 such that lower ends 93 thereof are submerged in water. Furthermore, the lower ends 93 are located above the duct 3. That is, the power supply wires 90 and the signal wire 91 are located at heights at which the same do not get caught in the propeller 4 and do not obstruct the flow of water generated by the propeller 4.
As described above, the power supply wires 90 and the signal wire 91 are moved in the forward-rearward direction inside the lead-out port 80a along the lead-out port 80a of the cowling 8 as the casing 7 is rotated by the steering 6.
According to the various preferred embodiments of the present invention described above, the following advantageous effects are achieved.
According to a preferred embodiment of the present invention, the power supply wires 90 and the signal wire 91 are located outside and along the casing 7 so as to pass in front of the steering shaft 5 along the rotation (steering) direction of the steering shaft 5 from the first side of the casing 7 to the second side of the casing 7 in the right-left direction in the plan view. Accordingly, the power supply wires 90 and the signal wire 91 are located so as to be wound around the steering shaft 5 in an arcuate shape having a relatively small curvature (an arcuate shape having a large radius) along the casing 7. Furthermore, the power supply wires 90 and the signal wire 91 are located along the rotation direction of the steering shaft 5 such that when the duct 3 (casing 7) is steered about the steering shaft 5, the duct 3 (casing 7) is steered while a state in which the power supply wires 90 and the signal wire 91 are wound in an arcuate shape having a relatively small curvature (an arcuate shape having a large radius) along the casing 7 is maintained. Therefore, large torsion (deformation) of the power supply wires 90 and the signal wire 91 is significantly reduced or prevented during steering of the duct 3 (casing 7), and thus a constraint on the steering angle of the duct 3 (casing 7) is significantly reduced or prevented. Furthermore, the power supply wires 90 and the signal wire 91 are located along the casing 7 such that spaces to provide the power supply wires 90 and the signal wire 91 are relatively reduced.
According to a preferred embodiment of the present invention, the power supply wires 90 and the signal wire 91 are located along the casing 7 so as to pass in front of the casing 7. Accordingly, using the front surface of the casing 7, the power supply wires 90 and the signal wire 91 are easily located so as to be wound around the steering shaft 5 in an arcuate shape having a relatively small curvature along the casing 7.
According to a preferred embodiment of the present invention, the first portions 92a of the power supply wires 90 and the signal wire 91 are located on the first side in the right-left direction, and the second portions 92b of the power supply wires 90 and the signal wire 91 introduced into the casing 7 are located on the second side in the right-left direction. Accordingly, as compared with a case in which the power supply wires 90 and the signal wire 91 are located on only one side in the right-left direction, the power supply wires 90 and the signal wire 91 have a larger arcuate shape (longer path length). Therefore, when the duct 3 is steered about the steering shaft 5, the duct 3 is steered while a state in which the power supply wires 90 and the signal wire 91 are wound in an arcuate shape having a relatively small curvature (an arcuate shape having a large radius) along the casing 7 in a larger range is maintained. Consequently, large torsion (deformation) of the power supply wires 90 and the signal wire 91 is further significantly reduced or prevented during steering of the duct 3, and thus a constraint on the steering angle of the duct 3 is further significantly reduced or prevented.
According to a preferred embodiment of the present invention, the casing 7 includes, on the second side in the right-left direction, the introduction hole 73 to allow the second portions 92b to be introduced into the casing 7 therethrough, and the second portions 92b are introduced into the introduction hole 73 obliquely from the lower front side toward the upper rear side, as viewed in the right-left direction. Accordingly, the power supply wires 90 and the signal wire 91 that hang down due to gravity are introduced from below, and thus action of large torsional and bending stresses on the power supply wires 90 and the signal wire 91 is further significantly reduced or prevented.
According to a preferred embodiment of the present invention, the power supply wires 90 are more vulnerable to torsion and easier to bend than the signal wire 91, and the signal wire 91 is harder to bend and more resistant to torsion than the power supply wires 90. Accordingly, even when the power supply wires 90 that are relatively vulnerable to torsion and the signal wire 91 that is relatively hard to bend are used, action of large torsional and bending stresses on the power supply wires 90 and the signal wire 91 is significantly reduced or prevented. Therefore, the steerable marine propulsion unit 100 is reliably wired.
According to a preferred embodiment of the present invention, the casing 7 includes the curved surface 72 that protrudes forward in the plan view, and the power supply wires 90 and the signal wire 91 are curved along the curved surface 72. Accordingly, the power supply wires 90 and the signal wire 91 are located along the curved surface 72, and thus when the duct 3 is steered about the steering shaft 5, the duct 3 is steered while a state in which the power supply wires 90 and the signal wire 91 are curved more smoothly and are wound in an arcuate shape having a relatively small curvature (an arcuate shape having a large radius) along the casing 7 is maintained. Therefore, large torsion (deformation) of the power supply wires 90 and the signal wire 91 is further significantly reduced or prevented during steering of the duct 3. Thus, action of large torsional and bending stresses on the power supply wires 90 and the signal wire 91 is further significantly reduced or prevented, and thus a constraint on the steering angle of the duct 3 is further significantly reduced or prevented.
According to a preferred embodiment of the present invention, the curved surface 72 has a substantially arcuate shape that protrudes forward in the plan view, and the power supply wires 90 and the signal wire 91 are placed in a substantially elliptical shape along the substantially arcuate curved surface 72. Note that the substantially arcuate shape includes a precise arcuate shape and shapes similar to the arcuate shape. Furthermore, the substantially elliptical shape includes a precise elliptical shape and shapes similar to the elliptical shape. Accordingly, the power supply wires 90 and the signal wire 91 are easily placed in a substantially elliptical shape along the curved surface 72, and thus the power supply wires 90 and the signal wire 91 are placed along the casing 7 in a larger range as compared with a case in which the power supply wires 90 and the signal wire 91 are placed in a circular shape. Therefore, action of large torsional and bending stresses on the power supply wires 90 and the signal wire 91 is further significantly reduced or prevented.
According to a preferred embodiment of the present invention, the casing 7 has a streamlined shape with the rotation axis direction of the propeller 4 as the longitudinal direction, and the power supply wires 90 and the signal wire 91 are located along the streamlined casing 7 such that the lower ends 93 thereof are submerged in water. Accordingly, using up to a region in which the power supply wires 90 and the signal wire 91 are submerged in water as spaces to provide the power supply wires 90 and the signal wire 91, the power supply wires 90 and the signal wire 91 are located along the casing 7, and thus entanglement of foreign matter with the power supply wires 90 and the signal wire 91 is significantly reduced or prevented.
According to a preferred embodiment of the present invention, the lower ends 93 of the power supply wires 90 and the signal wire 91 are located above the duct 3. Accordingly, obstruction of the power supply wires 90 and the signal wire 91 to the flow of water generated by the propeller 4 installed in the duct 3 is prevented.
According to a preferred embodiment of the present invention, the power supply wires 90 and the signal wire 91 are located along the casing 7 while being inclined so as to be located more forward toward the lower side. Accordingly, the power supply wires 90 and the signal wire 91 are located along the casing 7 in a larger range as compared with a case in which the power supply wires 90 and the signal wire 91 are located only in a substantially horizontal direction or a substantially vertical direction. Therefore, action of large torsional and bending stresses on the power supply wires 90 and the signal wire 91 is further significantly reduced or prevented.
According to a preferred embodiment of the present invention, the casing 7 includes, on the second side in the right-left direction, the introduction hole 73 to allow the power supply wires 90 and the signal wire 91 to be introduced into the casing 7 therethrough, the marine propulsion unit 100 further includes, above the casing 7, the cowling 8 to allow the power supply wires 90 and the signal wire 91 to pass therethrough, and the cowling 8 includes, on the side opposite to the introduction hole 73 in the right-left direction, the lead-out port 80a to lead the power supply wires 90 and the signal wire 91 from within the cowling 8 to the first side of the casing 7 in the right-left direction. Accordingly, the power supply wires 90 and the signal wire 91 are led downward from the lead-out port 80a located on the side opposite to the introduction hole 73 in the right-left direction and above the introduction hole 73, and thus the power supply wires 90 and the signal wire 91 are easily placed along the casing 7 while hanging down due to gravity.
According to a preferred embodiment of the present invention, the lead-out port 80a has an elongated shape that extends in the forward-rearward direction, and the power supply wires 90 and the signal wire 91 are moved in the forward-rearward direction inside the lead-out port 80a along the lead-out port 80a as the casing 7 is rotated. Accordingly, as compared with a case in which the power supply wires 90 and the signal wire 91 are completely constrained by the lead-out port 80a, torsional and bending stresses applied to the power supply wires 90 and the signal wire 91 during steering of the duct 3 are reduced, and a constraint on the steering angle of the duct 3 is further significantly reduced or prevented.
According to a preferred embodiment of the present invention, the marine propulsion unit 100 further includes the restrainer 2 to bundle the power supply wires 90 and the signal wire 91 at the predetermined position inside the cowling 8 and allow the power supply wires 90 and the signal wire 91 to pass through the predetermined position. Accordingly, the power supply wires 90 and the signal wire 91 are constrained at a position spaced relatively apart from the casing 7 to be steered. That is, the power supply wires 90 and the signal wire 91 are constrained at a position at which the influence of steering is relatively small. Therefore, action of large torsional and bending stresses on the power supply wires 90 and the signal wire 91 is further significantly reduced or prevented.
According to a preferred embodiment of the present invention, the marine propulsion unit 100 further includes the trim-tilt mechanism 1 to rotate the marine propulsion unit main body 100a in the upward-downward direction, and the restrainer 2 is freely rotatable about the axis that extends in the right-left direction when the marine propulsion unit main body 100a is rotated in the upward-downward direction by the trim-tilt mechanism 1. Accordingly, when the marine propulsion unit main body 100a is rotated in the upward-downward direction by the trim-tilt mechanism 1, the restrainer 2 is rotated to reduce torsional and bending stresses applied to the power supply wires 90 and the signal wire 91.
According to a preferred embodiment of the present invention, the predetermined position is located closer to the casing 7 than the trim-tilt shaft B30. Accordingly, the power supply wires 90 and the signal wire 91 are constrained at a position spaced apart by an appropriate distance not too far from the casing 7. Thus, large movement of the power supply wires 90 and the signal wire 91 located along the casing 7 is prevented during steering of the duct 3.
The preferred embodiments of the present invention described above are illustrative in all points and not restrictive. The extent of the present invention is not defined by the above description of the preferred embodiments but by the scope of the claims, and all modifications within the meaning and range equivalent to the scope of the claims are further included.
For example, while the marine propulsion unit preferably includes the trim-tilt mechanism in preferred embodiments described above, the present invention is not restricted to this. In the present invention, the marine propulsion unit may not include the trim-tilt mechanism.
While the marine propulsion unit preferably includes only one signal wire in preferred embodiments described above, the present invention is not restricted to this. In the present invention, the marine propulsion unit may alternatively include a plurality of signal wires.
While the power supply wires and the signal wire are preferably introduced into the casing from the introduction hole on the left side of the casing of the marine propulsion unit in preferred embodiments described above, the present invention is not restricted to this. In the present invention, the introduction hole may alternatively be provided on the right side of the casing of the marine propulsion unit, and the power supply wires and the signal wire may alternatively be introduced into the casing from the introduction hole on the right side. In such a case, the lead-out port is provided on the left side of the cowling.
While the introduction hole is preferably provided on the curved surface of the casing in preferred embodiments described above, the present invention is not restricted to this. In the present invention, the introduction hole may alternatively be provided in a portion rearward of the curved surface of the casing.
While the lower ends of the power supply wires and the signal wire of the marine propulsion unit are preferably submerged in water in preferred embodiments described above, the present invention is not restricted to this. In the present invention, the lower ends of the power supply wires and the signal wire may alternatively be covered with a cover so as to not be submerged in water.
While the casing of the marine propulsion unit preferably has a streamlined shape in preferred embodiments described above, the present invention is not restricted to this. In the present invention, the casing of the marine propulsion unit may alternatively have a shape other than a streamlined shape such as an elliptical shape.
While the predetermined position at which the power supply wires and the signal wire are bundled by the restrainer is preferably located closer to the casing than the trim-tilt shaft in preferred embodiments described above, the present invention is not restricted to this. In the present invention, the predetermined position at which the power supply wires and the signal wire are bundled by the restrainer may alternatively be located in the trim-tilt shaft or on the hull side relative to the trim-tilt shaft.
While the restrainer preferably includes the cylindrical portion and the annular restraining portion in preferred embodiments described above, the present invention is not restricted to this. In the present invention, the restrainer may alternatively include a string-shaped member, for example.
While the power supply wires and the signal wire are preferably moved in the forward-rearward direction inside the lead-out port as the casing is rotated in preferred embodiments described above, the present invention is not restricted to this. In the present invention, the power supply wires and the signal wire may alternatively be constrained in the lead-out port so as to not be moved inside the lead-out port as the casing is rotated.
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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2019-236264 | Dec 2019 | JP | national |