1. Field of the Invention
The present invention relates to a marine propulsion device.
2. Description of the Related Art
In an outboard motor, it is possible for a phenomenon to occur in which an engine is driven in a reverse direction (referred to below as an “inversion phenomenon”) by the propeller being rotated in a reverse orientation to a drive direction due to a torque applied by a water current. The cause for the occurrence of such an inversion phenomenon is described below. First, a boat operator sets a shift state to a neutral position in order to decelerate during forward progression. However, when a boat continues forward progression due to inertia, the propeller rotates normally due to water current hitting against the propeller. Next, the boat operator sets the shift state to a reverse position in order to further decelerate. At this time, if a rotation torque of the propeller due to the water current is larger than the engine drive torque, the engine stops, and is then driven in the reverse direction. When the engine is driven in the reverse direction, water is drawn into an exhaust passage due to a pump action of a cylinder. In this case, when water infiltrates into the cylinder, there is a possibility that the engine is damaged. Alternatively, there is a possibility that a catalyst is damaged due to submersion of the catalyst in water in the exhaust passage.
In an outboard motor disclosed in Japanese Laid-open Patent Application Publication No. H4-266593, a one-way clutch is disposed between a drive shaft and a pinion gear. In the outboard motor disclosed in Japanese Laid-open Patent Application Publication No. 2004-276726, a vertical shaft is divided into a first shaft and a second shaft, and an electromagnetic clutch is disposed between the first shaft and the second shaft. Both of these apparatuses have a structure in which the one-way clutch is engaged during transmission of a motive force from the engine to the propeller shaft, and the one-way clutch is disengaged and a motive force is not transmitted from the propeller shaft to the engine.
In addition, in a marine propulsion apparatus disclosed in Japanese Laid-open Patent Application Publication No. 2000-280983, the drive shaft is divided into a drive-side portion and a driven-side portion and a buffer apparatus is disposed between the drive-side portion and the driven-side portion. In the outboard motor disclosed in Japanese Laid-open Patent Application Publication No. 2006-183694, the drive shaft is divided into an upper drive shaft and a lower drive shaft and a damper structure is disposed between the upper section drive shaft and the lower section drive shaft. Both of these apparatuses have a structure in which the drive shaft is divided into two members and in which transmission of a motive force from the propeller shaft to the engine is controlled using a buffer member which is disposed between the two drive shaft members.
In addition, in the marine propulsion apparatus disclosed in Japanese Laid-open Patent Application Publication No. 2008-274970, the inversion phenomenon is detected by detecting a rotation angle of the crank shaft. In a case in which the inversion phenomenon is detected, the marine propulsion apparatus prevents the infiltration of water into the engine by forcibly transferring the shift gear to the neutral state.
In the apparatuses described above, it is possible to block or prevent the motive force which is transmitted from the propeller shaft to the engine due to the inversion phenomenon. However, it is necessary that the apparatuses of Japanese Laid-open Patent Application Publication No. H4-266593 and Japanese Laid-open Patent Application Publication No. 2004-276726 be segmented into an upstream portion and a downstream portion from a one-way clutch in a motive force transmission system in order to disengage the one-way clutch to block the motive force. As a result, there is a possibility that the durability of the motive force transmission system will be reduced during a normal motion since a portion that includes the one-way clutch is weak. The apparatuses of Japanese Laid-open Patent Application Publication No. 2000-280983 and Japanese Laid-open Patent Application Publication No. 2006-183694 have a similar problem to the apparatuses of Japanese Laid-open Patent Application Publication No. H4-266593 and Japanese Laid-open Patent Application Publication No. 2004-276726. Furthermore, in the apparatuses of Japanese Laid-open Patent Application Publication No. 2000-280983 and Japanese Laid-open Patent Application Publication No. 2006-183694, there is a possibility that the durability will be further reduced since the buffer member is made from a resin or the like.
In addition, in the apparatus of Japanese Laid-open Patent Application Publication No. 2008-274970, the shift state is transferred to the neutral state by operating a dog clutch after the inversion phenomenon is detected. As a result, a time lag occurs until the motive force in the reverse direction is blocked, and there is a possibility that infiltration of water into the engine will occur during the time lag.
In order to overcome the problems described above, preferred embodiments of the present invention provide a marine propulsion device in which it is possible to prevent the occurrence of an inversion phenomenon while maintaining the durability of a motive force transmission system.
A marine propulsion device according to a preferred embodiment of the present invention includes a motive force transmission system, a propeller shaft, a housing section, and a clutch. The motive force transmission system includes a crank shaft and a drive shaft which transmits a motive force from the crank shaft. The propeller shaft transmits the motive force from the drive shaft. The housing section houses the motive force transmission system. The clutch is attached between the motive force transmission system and the housing section. The clutch is configured to permit relative rotation between the motive force transmission system and the housing section by opening a connection between the motive force transmission system and the housing section during a normal rotation, i.e., a forward rotation, of the motive force transmission system. The clutch is configured to prevent the relative rotation between the motive force transmission system and the housing section by closing the connection between the motive force transmission system and the housing section during a reverse rotation of the motive force transmission system.
In a marine propulsion device according to a preferred embodiment of the present invention, the clutch connects the motive force transmission system and the housing section during the reverse rotation of the motive force transmission system. As a result of this arrangement, the relative rotation between the motive force transmission system and the housing section is prevented. That is, occurrence of the inversion phenomenon is prevented. Furthermore, it is possible to swiftly and effectively prevent an occurrence of the inversion phenomenon since detection of the inversion phenomenon and control of the shift state are not necessary. In addition, the clutch opens the connection of the motive force transmission system and the housing section during normal rotation of the motive force transmission system. As a result of this arrangement, the clutch permits the relative rotation between the motive force transmission system and the housing section during normal rotation of the motive force transmission system. Accordingly, it is not necessary to segment the upstream portion and the downstream portion of the clutch. As a result, it is possible to maintain the durability of the motive force transmission system.
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.
Below, a marine propulsion device according to a first preferred embodiment of the present invention will be described with reference to the drawings.
The engine 3 is disposed within the engine cover 6. The engine 3 is disposed on an exhaust guide 9. The exhaust guide 9 is disposed within the upper casing 7. For example, the engine 3 is a multicylinder engine, and includes a plurality of cylinders, a crank shaft 11, and a case section 10 which will be described below with reference to
The marine propulsion device 1 includes a motive force transmission system 4. The motive force transmission system 4 is housed in the housing section 2. The motive force transmission system 4 includes the crank shaft 11 described above, a drive shaft 12, and a forward and backward progression switching mechanism 13. The crank shaft 11 outputs a motive force from the engine 3. The crank shaft 11 preferably extends along a vertical direction. The drive shaft 12 transmits the motive force from the crank shaft 11. The drive shaft 12 is disposed within the upper casing 7 and the lower casing 8. The drive shaft 12 is disposed along an up-down direction within the upper casing 7 and the lower casing 8. An upper edge of the drive shaft 12 is linked to a lower edge of the crank shaft 11.
A propeller 14 is disposed in a lower section of the lower casing 8. The propeller 14 is disposed below the engine 3. The propeller 14 is linked to a propeller shaft 15. The propeller shaft 15 is preferably perpendicular to the drive shaft 12. The propeller shaft 15 is disposed along the front-back direction. The propeller shaft 15 is rotationally driven by the motive force transmitted from the drive shaft 12.
The propeller shaft 15 is linked to a lower section of the drive shaft 12 via the forward and backward progression switching mechanism 13. The forward and backward progression switching mechanism 13 is configured to switch the transmission direction of rotation of the propeller shaft 15 from the drive shaft 12. Accordingly, the motive force transmission system 4 rotates in the same direction during either the forward progression or the backward progression, but the propeller shaft 15 rotates in different directions during the forward progression and the backward progression of the marine propulsion device 1.
The forward and backward progression switching mechanism 13 is disposed within the lower casing 8.
The dog clutch 19 is attached to the propeller shaft 15 such that relative rotation therebetween is not possible. Accordingly, the dog clutch 19 integrally rotates with the propeller shaft 15. The dog clutch 19 can be selectively engaged with one of the forward progression bevel gear 17 and the backward progression bevel gear 18. The dog clutch 19 is arranged so as to move to a forward progression position, a backward progression position, or a neutral position along an axial direction of the propeller shaft 15.
The marine propulsion device 1 includes a shift apparatus 21. The dog clutch 19 is moved to the forward progression position, the backward progression position, and the neutral position by the shift apparatus 21. The shift apparatus 21 includes a shift sleeve 22, a shift rod 23, and a link member 24. The shift sleeve 22 is disposed within the propeller shaft 15. The shift sleeve 22 is attached so as to be able to move along the axial direction of the propeller shaft 15. One edge of the shift sleeve 22 is attached to the dog clutch 19 via an attachment pin 25. The other edge of the shift sleeve 22 is attached to a lower edge section of the shift rod 23 via the link member 24. The shift rod 23 rotates by being coupled with an action of a shift lever which is mounted on the boat. The link member 24 converts rotation motion of the shift rod 23 into linear motion along the axial direction of the propeller shaft 15 and transmits the motion to the shift sleeve 22. As a result of this arrangement, the dog clutch 19 moves to the forward progression position, the backward progression position, and the neutral position in accordance with an operation of the shift lever.
The forward progression bevel gear 17 and the backward progression bevel gear 18 are each selectively switched to a released state and a fixed state in accordance with the position of the dog clutch 19. In the forward progression position, the dog clutch 19 sets the forward progression bevel gear 17 in the fixed state and sets the backward progression bevel gear 18 in the released state. In the fixed state, the forward progression bevel gear 17 is not allowed to relatively rotate with respect to the propeller shaft 15. In the released state, the backward progression bevel gear 18 is allowed to relatively rotate with respect to the propeller shaft 15. In this case, the rotation of the drive shaft 12 is transferred to the propeller shaft 15 via the forward progression bevel gear 17. Thus, the propeller 14 rotates in a direction in which the boat progresses forward.
In the backward progression position, the dog clutch 19 sets the forward progression bevel gear 17 in the released state and sets the backward progression bevel gear 18 in the fixed state. In the released state, the forward progression bevel gear 17 is allowed to relatively rotate with respect to the propeller shaft 15. In the fixed state, the backward progression bevel gear 18 is not allowed to relatively rotate with respect to the propeller shaft 15. In this case, the rotation of the drive shaft 12 is transferred to the propeller shaft 15 via the backward progression bevel gear 18. Thus, the propeller 14 rotates in a direction in which the boat progresses backward. In a case in which the dog clutch 19 is positioned at the neutral position between the forward progression position and the backward progression position, the forward progression bevel gear 17 and the backward progression bevel gear 18 are allowed to each relatively rotate with respect to the propeller shaft 15. That is, the rotation from the drive shaft 12 is not transmitted to the propeller shaft 15, and the propeller shaft 15 is idle.
The lower casing 8 includes a first storage space 26, a second storage space 27, and a third storage space 28 at an inner portion thereof. The first storage space 26 extends downward from an upper section of the lower casing 8. The first storage space 26 houses the drive shaft 12. An upper section of the first storage space 26 includes an expanded space 29 which extends outward further than the other portions. The second storage space 27 extends downward from the upper section of the lower casing 8. An upper section of the second storage space 27 communicates with the expanded space 29 of the first storage space 26 via a communication passage 291. The third storage space 28 is disposed below the first storage space 26 and the second storage space 27. The third storage space 28 communicates with a lower section of the first storage space 26. The third storage space 28 communicates with a lower section of the second storage space 27. The third storage space 28 houses the forward and backward progression switching mechanism 13 and the propeller shaft 15.
The third storage space 28 houses an inner housing 31. The inner housing 31 houses a shaft section of the backward progression bevel gear 18. In addition, the inner housing 31 houses a portion of the propeller shaft 15.
Lubricating oil is filled into the first storage space 26, the second storage space 27, and the third storage space 28. A groove 121 with a spiral shape is provided on the circumferential surface of the drive shaft 12. The lubricating oil is drawn up to the first storage space 26 from the third storage space 28 by the rotation of the drive shaft 12. Then, the lubricating oil flows into the second storage space 27 from the first storage space 26 through the communication passage 291, and after this, returns to the third storage space 28. In this manner, a lubricating oil system is configured so that the lubricating oil circulates in the first storage space 26, the second storage space 27, and the third storage space 28.
The marine propulsion device 1 includes a clutch 32. The clutch 32 is stored in the expanded space 29 of the first storage space 26.
The clutch 32 includes a housing section-side gear 33 and a drive shaft-side gear 34. The drive shaft-side gear 34 is attached to the drive shaft 12. The housing section-side gear 33 is attached to the lower casing 8. The drive shaft-side gear 34 includes a holder housing 35 and a gear member 36.
As shown in
In the marine propulsion device 1 according to the present preferred embodiment, the clutch 32 connects the drive shaft 12 and the lower casing 8 during reverse rotation of the motive force transmission system 4. As a result of this arrangement, relative rotation between the drive shaft 12 and the lower casing 8 is prevented. That is, it is possible to prevent the occurrence of the inversion phenomenon. Furthermore, it is possible to swiftly and effectively prevent the occurrence of the inversion phenomenon since detection of the inversion phenomenon and control of the shift state are not necessary. In addition, the clutch 32 opens the connection of the drive shaft 12 and the lower casing 8 during normal rotation of the motive force transmission system 4. As a result of this arrangement, the clutch 32 permits the relative rotation between the drive shaft 12 and the lower casing 8 during normal rotation of the motive force transmission system 4. Accordingly, it is not necessary to segment the upstream portion and the downstream portion of the drive shaft 12 using the clutch 32. As a result, it is possible to maintain durability of the motive force transmission system 4.
The clutch 32 is disposed inside the first storage space 26. In addition, the forward and backward progression switching mechanism 13 is disposed in the third storage space 28. The first storage space 26 communicates with the second storage space 27 and the third storage space 28, and the lubricating oil circulates in the first storage space 26, the second storage space 27, and the third storage space 28 due to the rotation of the drive shaft 12. Accordingly, the clutch 32 and the forward and backward progression switching mechanism 13 are lubricated by the same lubricating system.
The drive shaft 12 is inserted into the holder housing 35 by press-fitting, for example. As a result, it is possible for the drive shaft 12 to slip with respect to the holder housing 35 when an excessive load is imparted to the drive shaft 12 due to reverse rotation of the drive shaft 12. Accordingly, for example, compared to a case in which the drive shaft 12 and the holder housing 35 are connected by a spline, it is possible to prevent damage to the drive shaft 12 or the holder housing 35. In the same manner, the housing section-side gear 33 is inserted into the lower casing 8 by press-fitting, for example. As a result, it is possible for the housing section-side gear 33 to slip with respect to the lower casing 8 when an excessive load is imparted to the housing section-side gear 33 due to the reverse rotation of the drive shaft 12. As a result, it is possible to prevent damage to the housing section-side gear 33 or the lower casing 8.
Next, a marine propulsion device according to a second preferred embodiment of the present invention will be described.
The first tapered bearing 42 supports the third shaft section 12c of the drive shaft 12. A nut 46 and a lid member 41 are disposed above the first tapered bearing 42. The nut 46 is disposed between the first tapered bearing 42 and the lid member 41. A gap between the lid member 41 and the fourth shaft section 12d of the drive shaft 12 is sealed by the seal member 39.
The second tapered bearing 43 supports the first shaft section 12a of the drive shaft 12. The second tapered bearing 43 is disposed in a position which is closer to a propeller shaft 15 than is the first tapered bearing 42. That is, the second tapered bearing 43 is disposed further downward than the first tapered bearing 42. The outer diameter of the second tapered bearing 43 is smaller than the outer diameter of the first tapered bearing 42.
The clutch 44 is attached between the drive shaft 12 and the lower casing 8. The clutch 44 is disposed between the first tapered bearing 42 and the second tapered bearing 43. The outer diameter of the clutch 44 is smaller than the outer diameter of the first tapered bearing 42. As a result, a spacer 45 is disposed between the outer circumferential surface of the clutch 44 and the inner surface of the expanded space 29. The spacer 45 is inserted into the inner circumferential surface of the expanded space 29 by press-fitting, for example, and is fixed so as not to relatively rotate with respect to the expanded space 29. In the marine propulsion device according to the second preferred embodiment, the outer diameter of the second shaft section 12b is larger than the outer diameter of the first shaft section 12a. The clutch 44 is preferably a one-way clutch. That is, the clutch 44 permits relative rotation between the drive shaft 12 and the lower casing 8 by opening a connection between the drive shaft 12 and the lower casing 8 during normal rotation of the drive shaft 12. The clutch 44 prevents the relative rotation between the drive shaft 12 and the lower casing 8 by closing a connection between the drive shaft 12 and the lower casing 8, i.e., connecting the drive shaft 12 with the lower casing 8, during reverse rotation of the drive shaft 12.
Description of other configurations of the marine propulsion device according to the second preferred embodiment will be omitted since the configurations are preferably the same as the marine propulsion device 1 according to the first preferred embodiment. In the marine propulsion device according to the second preferred embodiment, it is possible to prevent the occurrence of the inversion phenomenon while maintaining durability of the motive force transmission system in the same manner as the marine propulsion device 1 according to the first preferred embodiment.
As shown in
Alternatively, as shown in
Next, a marine propulsion device according to a third preferred embodiment of the present invention will be described.
The clutch 56 is preferably a one-way clutch. That is, the clutch 56 permits relative rotation between the backward progression bevel gear 18 and the inner housing 31 by opening a connection between the backward progression bevel gear 18 and the inner housing 31 during normal rotation of the motive force transmission system 4. In addition, the clutch 56 prevents relative rotation between the backward progression bevel gear 18 and the inner housing 31 by closing a connection between the backward progression bevel gear 18 and the inner housing 31 during reverse rotation of the motive force transmission system 4. The inner diameter of the clutch 56 is smaller than the inner diameter of the first bearing 54. In addition, the inner diameter of the second bearing 55 is smaller than the inner diameter of the clutch 56. The outer diameter of the clutch 56 is smaller than the outer diameter of the first bearing 54. In addition, the outer diameter of the second bearing 55 is larger than the outer diameter of the clutch 56. A spacer 57 is disposed between the outer circumferential surfaces of the first bearing 54, the second bearing 55, and the clutch 56 and the inner circumferential surface of the inner housing 31.
Description of other configurations of the marine propulsion device according to the third preferred embodiment will be omitted since the configurations are preferably the same as the marine propulsion device 1 according to the first preferred embodiment. In the marine propulsion device according to the third preferred embodiment, in the same manner as the marine propulsion device 1 according to the first preferred embodiment, it is possible to prevent the occurrence of the inversion phenomenon while maintaining durability of the motive force transmission system.
Preferred embodiments of the present invention have been described above, but the present invention is not limited to the preferred embodiments described above and various changes are possible within a scope which does not depart from the gist of the present invention. For example, preferred embodiments of the present invention are not limited to an outboard motor and may be applied to another marine propulsion device such as an inboard-outdrive engine.
The clutch may be attached to a portion other than the lower casing 8 or the drive shaft 12. For example, the clutch may be attached to the upper casing 7. Alternatively, the clutch may be attached between the crank shaft 11 and the case section 10 of the engine 3 in the same manner as the clutch 58 which is shown in
In the third preferred embodiment described above, the clutch 56 preferably is attached to the backward progression bevel gear 18, but the clutch may be attached to the forward progression bevel gear 17. Alternatively, the clutch may be attached to the pinion gear 16. The clutch is not limited to a one-way clutch, and may be a clutch such as an electromagnetic clutch.
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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2012-119449 | May 2012 | JP | national |