1. Field of the Invention
The present invention relates to a vessel propulsion apparatus.
2. Description of the Related Art
Outboard motors include engines that generate power and engine cowlings that house the engines. Wiring and piping are disposed in the interior of the engine cowlings. For example, Japanese Patent Application Publication No. 2010-25004 discloses piping 100 that is disposed in a cowling. As shown in
In the outboard motor, downsizing of the engine cowling that houses the engine is demanded in some cases. In some other cases, it is demanded to increase the power of the outboard motor that will lead to an increase in the size of the engine. Thus, conflicting demands of an increase in the size of the engine and downsizing of the engine cowling are sometimes made.
In Japanese Patent Application Publication No. 2010-25004, the piping 100 extends in the front-rear direction on the left side of the engine main body. In this configuration, when the cowling is downsized, the piping may wear or be damaged due to sliding of the cowling and piping, because the inner surface of the cowling approaches the piping. Therefore, it is difficult to downsize the cowling. In particular, when the engine main body is increased in size, the piping approaches the inner surface of the cowling, so that it is more difficult to downsize the cowling. In some situations, an increase in the size of the engine cowling is thus required.
In order to overcome the previously unrecognized and unsolved challenges described above, a preferred embodiment of the present invention provides a vessel propulsion apparatus including an engine main body including a crankshaft that is rotatable about a rotation axis extending in an up-down direction; auxiliary machinery mounted on the engine main body; a bracket that couples the auxiliary machinery to the engine main body, the bracket including a first mounting portion mounted on the engine main body, a second mounting portion mounted on the auxiliary machinery, a coupling portion coupling the first mounting portion and the second mounting portion, and a holding portion provided in the coupling portion and configured to hold wiring or piping; and an engine cowling that houses the engine main body, the auxiliary machinery, and the bracket. The wiring may be a signal line to transmit an electrical signal, or may be a power line to supply the electric power of a power supply to electrical equipment. The piping may be piping to guide gas or liquid, or may be piping to guide both of gas and liquid.
According to this arrangement of a preferred embodiment of the present invention, the crankshaft that is rotatable about the rotation axis extending in the up-down direction is provided in the engine main body. The engine main body is disposed inside the engine cowling. Similarly, the auxiliary machinery to assist the engine main body and the bracket to mount the auxiliary machinery on the engine main body are disposed inside the engine cowling. The first mounting portion of the bracket is mounted on the engine main body, and the second mounting portion of the bracket is mounted on the auxiliary machinery. The auxiliary machinery is thus coupled to the engine main body.
The bracket holds wiring or piping (hereinafter, referred to as “wiring or the like”) by the holding portion provided in the coupling portion that couples the first mounting portion and the second mounting portion each other. That is, the bracket not only mounts the auxiliary machinery on the engine main body, but also holds the wiring or the like. Thus, as compared with a case of providing a bracket for the wiring or the like in addition to a bracket for the auxiliary machinery, the number and size of the structural elements that are housed inside the engine cowling are reduced. The engine cowling is thus downsized. Further, even if the engine main body is increased in size, an increase in the size and number of structural elements included in the engine cowling is minimized or prevented, so that an increase in the size of the engine cowling is minimized or prevented.
In a preferred embodiment of the present invention, the holding portion is preferably disposed farther inward than the auxiliary machinery with respect to an inner surface of the engine cowling.
According to this arrangement of a preferred embodiment of the present invention, the distance from the inner surface of the engine cowling to the holding portion of the bracket preferably is longer than the distance from the inner surface of the engine cowling to the auxiliary machinery. The holding portion of the bracket is thus disposed farther inward than the auxiliary machinery with respect to the inner surface of the engine cowling. Therefore, the wiring or the like does not easily contact the engine cowling. Further, even when the wiring or the like is disposed outward as a result of an increase in the size of the engine main body, the wiring or the like does not easily contact the engine cowling. As a result, wearing of or damage to the wiring or the like due to sliding of the wiring or the like and the engine cowling is significantly reduced or prevented.
In a preferred embodiment of the present invention, the holding portion preferably includes a first piping mounting portion in which first piping is mounted and a second piping mounting portion in which second piping is mounted. The bracket may further include a cylindrical inner peripheral surface that defines a penetration hole as a relay passage extending from the interior of the first piping to the interior of the second piping.
According to this arrangement of a preferred embodiment of the present invention, the first piping and the second piping that define a common passage are mounted in the first piping mounting portion and the second piping mounting portion of the bracket, respectively, and the inner peripheral surface of the bracket defines a penetration hole as a relay passage extending from the interior of the first piping to the interior of the second piping. That is, the bracket not only holds the first piping and the second piping, but also defines a common passage with the first piping and the second piping.
In this manner, the bracket itself defines a passage, and therefore, the length of the piping is reduced. The structural elements provided in the cowling are thus reduced in size and number. Further, because the length of the piping is reduced, displacement of the piping by vibration is significantly reduced or prevented. A positional change of the piping is thus prevented. Moreover, because the first piping and the second piping are mounted on the bracket that is higher in rigidity than the first piping and the second piping and the bracket is mounted on the engine main body, displacement of the first piping and the second piping is further reduced or prevented. Wearing of or damage to the piping due to sliding of the piping and another member is thus further reduced or prevented.
In a preferred embodiment of the present invention, at least a portion of the holding portion preferably surrounds the periphery of the wiring or piping.
According to this arrangement of a preferred embodiment of the present invention, the wiring or the like is disposed in a portion in the interior of the bracket, and the periphery of the wiring or the like is surrounded by the holding portion of the bracket. Movement of the wiring or the like is thus prevented by the bracket. The wiring or the like is thus increased in stability. Therefore, wearing of and damage to the wiring or the like due to sliding of the wiring or the like and another member is further reduced or prevented.
In a preferred embodiment of the present invention, at least a portion of the holding portion preferably has a C-shaped cross-section disposed on the periphery of the wiring or piping.
According to this arrangement of a preferred embodiment of the present invention, the holding portion of the bracket includes a C-shaped portion that has a C-shaped cross-section, and the wiring or the like penetrates the C-shaped portion. The periphery of the wiring or the like is surrounded by the C-shaped portion. The force that restrains the wiring or the like by the bracket is thus increased, and movement of the wiring or the like is reliably prevented. Wearing of or damage to the wiring or the like due to sliding of the wiring or the like and another member is thus further reduced or prevented.
In a preferred embodiment of the present invention, at least a portion of the holding portion preferably includes an annular cross-section continuing throughout an entire circumference of the holding portion and disposed on the periphery of the wiring or piping.
According to this arrangement of a preferred embodiment of the present invention, the holding portion of the bracket includes an annular portion that has an annular cross-section continuing throughout the entire circumference of the holding portion, and the wiring or the like penetrates the annular portion. The periphery of the wiring or the like is surrounded by the annular portion. Thus, the force that restrains the wiring or the like by the bracket is increased and detaching of the wiring or the like from the bracket is reliably prevented. Wearing of and damage to the wiring or the like due to sliding of the wiring or the like and another member is thus further reduced or prevented.
In a preferred embodiment of the present invention, the holding portion preferably includes a cylindrical inner peripheral surface that defines a penetration hole penetrating the coupling portion in a longitudinal direction of the wiring or piping.
According to this arrangement of a preferred embodiment of the present invention, the inner peripheral surface of the holding portion defines a penetration hole extending in the longitudinal direction of the wiring or the like, and the penetration hole penetrates the coupling portion in the longitudinal direction of the wiring or the like. The wiring or the like is inserted into the penetration hole, and a portion of the wiring or the like is disposed inside the penetration hole. Because the inner peripheral surface of the holding portion continues throughout its entire circumference, movement of the wiring or the like in the radial direction of the holding portion is reliably prevented. Further, because the inner peripheral surface of the holding portion preferably has an elongated cylindrical shape extending from one end surface of the coupling portion to another end surface of the coupling portion, movement of the wiring or the like is prevented over a longer distance in terms of the longitudinal direction of the wiring or the like. Wearing of and damage to the wiring or the like due to sliding of the wiring or the like and another member is thus further reduced or prevented.
In a preferred embodiment of the present invention, the holding portion preferably is disposed over the engine main body, and in a gap in a horizontal direction between the engine main body and the auxiliary machinery.
According to this arrangement of a preferred embodiment of the present invention, the holding portion of the bracket is disposed over the engine main body, and the holding portion and the engine main body overlap each other in a plan view. Thus, the area occupied by structural elements in a plan view is significantly reduced as compared with a case in which the holding portion and the engine main body do not overlap each other in a plan view. Further, because the holding portion of the bracket is disposed in a gap in the horizontal direction between the engine main body and the auxiliary machinery, the wiring or the like does not easily contact the engine cowling. Therefore, wearing of or damage to the wiring or the like due to sliding of the wiring or the like and the engine cowling is further reduced or prevented.
In a preferred embodiment of the present invention, the auxiliary machinery preferably includes a starter motor mounted on the engine main body via the bracket, and a ring gear that rotates together with the crankshaft by being driven to rotate by the starter motor. The holding portion preferably is disposed in a gap in a horizontal direction between the engine main body and the starter motor, and in a gap in an up-down direction between the engine main body and the ring gear.
According to this configuration of a preferred embodiment of the present invention, the holding portion of the bracket is disposed in a gap in the horizontal direction between the engine main body and the starter motor. The space in the horizontal direction between the engine main body and the starter motor is thus used as a space to dispose the holding portion. Further, the holding portion of the bracket is disposed in a gap in the up-down direction between the engine main body and the ring gear. Thus, the space in the up-down direction between the engine main body and the ring gear is also used as a space to dispose the holding portion. In this manner, because the space between the engine main body and the auxiliary machinery is effectively used, the number and size of structural elements included in the engine cowling is significantly reduced or minimized. Accordingly, an increase in a total size of the number and size of structural elements included in the engine cowling is minimized or prevented. An increase in the size of the engine cowling is thus minimized or prevented.
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.
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The engine 8 is preferably an internal combustion engine. The engine 8 rotates in a fixed rotation direction. The rotation of the engine 8 is transmitted to the propeller 13 by the power transmission device 9. The propeller 13 is thus caused to rotate together with the propeller shaft 12 and a thrust that propels the vessel forward or in reverse is generated. Also, the direction of a rotation transmitted from the drive shaft 10 to the propeller shaft 12 is switched by the forward/reverse switching mechanism 11. The rotation direction of the propeller 13 and the propeller shaft 12 is thus switched between a normal rotation direction (clockwise direction when the propeller 13 is viewed from the rear) and a reverse rotation direction (direction of rotation opposite to the normal rotation direction). The direction of thrust is thus switched.
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The pinion 62 is movable up and down between an engaged position where the pinion 62 engages with the ring gear 59 (position shown in
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As described above, in the present preferred embodiment, the crankshaft 28 that is rotatable about the crank axis Ac extending in the up-down direction is provided in the engine main body 20. The engine main body 20 is disposed inside the engine cowling 14. Similarly, the starter unit 60, as an example of the auxiliary machinery, and the bracket 64, to mount the starter unit 60 on the engine main body 20, are disposed inside the engine cowling 14. The first mounting portion 67 of the bracket 64 is mounted on the engine main body 20, and the second mounting portion 68 of the bracket 64 is mounted on the starter unit 60. The starter unit 60 is thus coupled to the engine main body 20.
The bracket 64 holds the blowby hose 56, as an example of piping, by the holding portion 71 provided in the coupling portion 70 that couples the first mounting portion 67 and the second mounting portion 68. That is, the bracket 64 not only mounts the starter unit 60 on the engine main body 20, but also holds the blowby hose 56. Thus, as compared with a case of providing a bracket for the blowby hose 56 in addition to a bracket for the starter unit 60, the number and size of structural elements included in the engine cowling 14 is significantly reduced or minimized. The engine cowling 14 is thus downsized. Further, even when the engine main body 20 is increased in size, an increase in the number and size of structural elements included in the engine cowling as a whole is minimized or prevented, so that an increase in the size of the engine cowling 14 is minimized or prevented.
Also, in the present preferred embodiment, the distance from the inner surface 14a of the engine cowling 14 to the holding portion 71 of the bracket 64 preferably is longer than the distance from the inner surface 14a of the engine cowling 14 to the starter unit 60. The holding portion 71 of the bracket 64 is thus disposed farther inward than the starter unit 60 with respect to the inner surface 14a of the engine cowling 14. Therefore, hindering the downsizing of the engine cowling 14 by interference of the blowby hose 56 and the engine cowling 14 is avoided. Further, contact of the blowby hose 56 with the engine cowling 14 due to an outward movement of the blowby hose 56 resulting from an increase in the size of the engine main body 20 is prevented. An increase in the size of the engine cowling 14 is thus minimized or prevented.
Also, in the present preferred embodiment, the holding portion 71 of the bracket 64 is disposed over the engine main body 20, and the holding portion 71 and the engine main body 20 overlap each other in a plan view. Thus, the area occupied by the structural elements contained in the engine cowling in a plan view is significantly reduced as compared with a case in which the holding portion 71 and the engine main body 20 do not overlap each other in a plan view. Further, because the holding portion 71 of the bracket 64 is preferably disposed in a gap in the horizontal direction between the engine main body 20 and the starter unit 60, the blowby hose 56 does not easily contact the engine cowling 14. Therefore, wearing of and damage to the blowby hose 56 due to sliding of the blowby hose 56 and the engine cowling 14 is reduced or prevented.
Also, in the present preferred embodiment, the holding portion 71 of the bracket 64 is preferably disposed in a gap in the horizontal direction between the engine main body 20 (crank case 30 and cylinder body 31) and the starter motor 61. The space in the horizontal direction between the engine main body 20 and the starter motor 61 is thus used as a space to dispose the holding portion 71. Further, the holding portion 71 of the bracket 64 is disposed in a gap in the up-down direction between the engine main body 20 (crank case 30 and cylinder body 31) and the ring gear 59. Thus, the space in the up-down direction between the engine main body 20 and the ring gear 59 is also used as a space to dispose the holding portion 71. In this manner, because the space between the engine main body 20 and the starter unit 60 is effectively used, the number and size of structural elements included in the engine cowling 14 are significantly reduced or minimized. Accordingly, an increase in the overall size of the area occupied by the structural elements in the engine cowling 14 as a whole is minimized or prevented. An increase in the size of the engine cowling 14 is thus minimized or prevented.
Also, in the present preferred embodiment, the first piping 65 and the second piping 66 that define a common passage (second blowby gas passage 55) are preferably mounted in the first piping mounting portion 75 and the second piping mounting portion 76 of the bracket 64, respectively. The inner peripheral surface 64a of the bracket 64 defines a penetration hole as a relay passage extending from the interior of the first piping 65 to the interior of the second piping 66. That is, the bracket 64 not only holds the first piping 65 and the second piping 66, but also defines a common passage with the first piping 65 and the second piping 66.
In this manner, the bracket 64 itself defines a passage, and therefore, the length of the blow by hose 56 is significantly reduced. The number and size of structural elements included in the engine cowling 14 is thus significantly reduced or minimized. Further, because the length of the blowby hose 56 is reduced, displacement of the blowby hose 56 by vibration is reduced or prevented. A positional change of the blowby hose 56 is thus prevented. Moreover, because the blowby hose 56 is mounted on the bracket 64 that is higher in rigidity than the blowby hose 56 and the bracket 64 is mounted on the engine main body 20, displacement of the blowby hose 56 is further reduced or prevented. Wearing of and damage to the blowby hose 56 due to sliding of the blowby hose 56 and another member is thus further reduced or prevented.
Although preferred embodiments of the present invention have been described above, the present invention is not restricted to the contents of the preferred embodiments and various modifications are possible within the scope of the present invention.
For example, in the above-described preferred embodiments, a description has been given of a case in which the blowby hose 56 preferably includes double piping (first piping 65 and second piping 66), for example. However, the blowby hose 56 may include triple or more piping, or may be of single piping.
Also, in the above-described preferred embodiments, a description has been given of a case where the bracket 64 preferably holds the blowby hose 56 as an example of piping. However, the bracket 64 may hold piping other than the blowby hose 56 or may hold wiring such as a wire harness. Alternatively, the bracket 64 may hold both wiring and piping.
Also, in the above-described preferred embodiments, a description has been given of a case where the blowby hose 56 is preferably disposed farther inward than the starter unit 60. However, the blowby hose 56 may be disposed farther outward than the starter unit 60 with respect to the inner surface 14a of the engine cowling 14.
Also, the bracket 64 may be coupled with electric auxiliary machinery such as an ECU, not the starter unit 60.
Also, in the above-described preferred embodiments, a description has been given of a case where the bracket 64 and the ring gear 59 preferably overlap each other in a plan view. However, the bracket 64 may be disposed so as not to overlap the ring gear 59 in a plan view.
Also, in the above-described preferred embodiments, a description has been given of a case where the bracket 64 is preferably a member separate from the engine main body 20 and the starter unit 60. However, the bracket 64 may be integral with a portion or a whole of the starter unit 60.
Also, in the above-described preferred embodiments, a description has been given of a case where the bracket 64 is preferably coupled to both of the crank case 30 and the cylinder body 31 by the two first bolts B1. However, the bracket 64 may be coupled to one of the crank case 30 and the cylinder body 31 or may be coupled to components of the engine main body 20 other than the crank case 30 and the cylinder body 31.
Also, in the above-described preferred embodiments, a description has been given of a case where the bracket 64 is preferably coupled to the engine main body 20 at two mounting positions spaced apart in the horizontal direction and coupled to the auxiliary machinery (starter unit 60) at two mounting positions spaced apart in the horizontal direction. However, the bracket 64 may be coupled to the engine main body 20 at a plurality of mounting positions spaced apart in the up-down direction. Similarly, the bracket 64 may be coupled to the auxiliary machinery at a plurality of mounting positions spaced apart in the up-down direction.
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Also, in the above-described preferred embodiments, a description has been given of a case where the blowby hose 56 is preferably held by the bracket 64 between a connecting position (first connecting position) of the blowby hose 56 and the head cover 33 and a connecting position (second connecting position) of the blowby hose 56 and the intake device. However, the blowby hose 56 may be held by a plurality of brackets between the first connecting position and the second connecting position. In this case, the blowby hose 56 is held by the plurality of brackets, and therefore, stability of the blowby hose 56 is further increased.
Also, in the above-described preferred embodiments, a description has been given of a case where the bracket 64 preferably defines a portion of the second blowby gas passage 55. However, the bracket 64 may not define a portion of the second blowby gas passage 55. For example, as shown in
In the bracket 64A shown in
According to this arrangement of a preferred embodiment of the present invention, because the periphery of the blowby hose 56 is surrounded by the holding portion 71A of the bracket 64A, movement of the blowby hose 56 is prevented by the bracket 64A. Further, because the holding portion 71A has a C-shaped section, the force that restrains the blowby hose 56 by the bracket 64A is increased, and movement of the blowby hose 56 is reliably prevented. Wearing of or damage to the blowby hose 56 due to sliding of the blowby hose 56 and another member is thus reduced or prevented.
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Also, in the bracket 64C shown in
Also, two or more of all preferred embodiments described above may be combined.
The present application corresponds to Japanese Patent Application No. 2013-169812 filed on Aug. 19, 2013 in the Japan Patent Office, and the entire disclosure of this application is incorporated herein by reference.
While preferred embodiments of the present invention have been described above, it is to be understood that variations and modifications will be apparent to those skilled in the art without departing from the scope and spirit of the present invention. The scope of the present invention, therefore, is to be determined solely by the following claims.
Number | Date | Country | Kind |
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2013-169812 | Aug 2013 | JP | national |