1. Field of the Invention
The present invention relates to an engine unit.
2. Description of the Related Art
An engine unit includes an oil tank configured to store lubricating oil of an engine. For example, the oil tank is disposed forward of the engine in a structure described in Japan Laid-open Patent Application Publication No. JP-A-H09-317431. The oil tank includes upper and lower portions that are provided as discrete elements and are joined to each other.
When fabricating an oil tank by die casting, the oil tank is required to have a draft angle on its inner surface so as to facilitate its removal from a die. Therefore, when the oil tank is structured to be split into the upper and lower portions as described above, the thickness of the upper portion of the oil tank increases upwardly. On the other hand, the thickness of the lower portion of the oil tank increases downwardly. Put differently, the thickness of the oil tank increases with the distance from a joint surface between the upper and lower portions. Especially when the oil tank has a shape elongated in the up-and-down direction, the thickness of the oil tank further increases. This results in the drawback of reducing the capacity of an oil storage space inside the oil tank.
Preferred embodiments of the present invention provide an engine unit including a large oil storage space inside an oil tank.
An engine unit according to a preferred embodiment of the present invention includes an engine body, a crankshaft, and an oil tank. The engine body includes a cylinder unit and a crankcase. The crankshaft is accommodated in the crankcase and extends in a horizontal or substantially horizontal direction. The oil tank is located at a lateral portion of the engine body. The oil tank includes a tank body, a first component, and a second component. The first component is separate from the tank body and joined to the tank body. The second component is separate from the tank body and joined to the tank body. A first joint surface between the tank body and the first component extends in a first direction different from that of a second direction in which a second joint surface between the tank body and the second component extends.
In the engine unit according to the present preferred embodiment, the oil tank is configured preferably by joining the tank body, the first component, and the second component which are separate elements from each other. Further, the first joint surface between the tank body and the first component extends in the first direction different from that of the second direction in which the second joint surface between the tank body and the second component extends. Thus, when fabricating the tank body, for example, preferably by die casting, draft angles are provided on the tank body in a plurality of directions. Accordingly, the thickness of the oil tank is further reduced compared to when a draft angle is provided only in one direction (e.g., the up-and-down direction). Consequently, a large oil storage space is provided inside the oil tank.
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 will be hereinafter explained with reference to the attached drawings.
The vehicle 100 includes the engine unit 1 and a vehicle body 2. The vehicle body 2 includes a hull 4 and a jet propulsion unit 3. The engine unit 1 and the jet propulsion unit 3 are installed in the hull 4. The jet propulsion unit 3 is configured to be driven by the engine unit 1.
The hull 4 includes an engine compartment 4a in the interior thereof. The engine compartment 4a accommodates the engine unit 1, a fuel tank 5, and so forth. A seat 6 is attached to the hull 4. The seat 6 is disposed above the engine unit 1. The seat 6 is a saddle-riding type seat. A steering member 7 is disposed in front of the seat 6 in order to steer the hull 4. It should be noted that in the following explanation, directional terms “front”, “rear,” “right” and “left” and their related terms refer to directions as seen from a rider seated on the seat 6 in a position of the vehicle 100 floating in still water.
The engine unit 1 includes a power transmission shaft 11. The power transmission shaft 11 extends in the back-and-forth direction. The jet propulsion unit 3 is configured to suck in water surrounding the hull 4 and eject the sucked in water. The jet propulsion unit 3 includes an impeller shaft 90, an impeller 91, an impeller housing 92, a nozzle 93, a deflector 94, and a reverse gate 95. The impeller shaft 90 extends rearwardly from the engine compartment 4a. The front portion of the impeller shaft 90 is connected to the power transmission shaft 11. The rear portion of the impeller shaft 90 is introduced into the impeller housing 92 through a water suction portion 4b of the hull 4. The impeller housing 92 is connected to the rear portion of the water suction portion 4b. The nozzle 93 is disposed behind the impeller housing 92.
The impeller 91 is attached to the rear portion of the impeller shaft 90. The impeller 91 is disposed in the interior of the impeller housing 92. The impeller 91 is configured to be rotated together with the impeller shaft 90 in order to suck in water from the water suction portion 4b of the hull 4. The impeller 91 is configured to cause the nozzle 93 to rearwardly eject the sucked in water. The deflector 94 is disposed behind the nozzle 93. The deflector 94 is configured to switch the direction of water ejected from the nozzle 93 in the right-and-left direction. The reverse gate 95 is disposed behind the deflector 94. The reverse gate 95 is configured to switch the direction of water ejected from the nozzle 93 and the deflector 94 to the front.
The engine unit 1 includes the power transmission shaft 11 and an engine body 12. The power transmission shaft 11 protrudes rearwardly from the engine body 12. The power transmission shaft 11 is coupled to the impeller shaft 90.
The cylinder unit 14 is disposed above the crankcase 13. The cylinder unit 14 includes a cylinder body 17 and a cylinder head 18. It should be noted that the head cover 15 and the cylinder head 18 are not shown in
As shown in
The coupling shaft 22 is a discrete element preferably separate from the crankshaft 21, and is coupled to the crankshaft 21. When described in detail, the coupling shaft 22 is coupled to the rear end of the crankshaft 21. The coupling member 23 is a discrete element preferably separate from the coupling shaft 22, and is coupled to the coupling shaft 22. When described in detail, the coupling member 23 is connected to the rear end of the coupling shaft 22. As shown in
The cylinder body 17 includes a plurality of cylinders 171 disposed in alignment in the back-and-forth direction. The axes of the respective cylinders 171 preferably extend in the up-and-down direction. Pistons 172 are disposed inside the cylinders 171 on a one-to-one basis. Each piston 172 is coupled to the crankshaft 21 through a connecting rod 173. Combustion chambers 181 are provided inside the cylinder head 18. Spark plugs 182 are attached to the cylinder head 18.
It should be noted that in
A camshaft 26 is disposed inside the cylinder head 18 and the head cover 15. When the cam shaft 26 is driven, an intake valve and an exhaust valve (not shown in the drawings), mounted to each combustion chamber 181, are configured to be opened and closed. A first sprocket 261 is attached to the front end of the cam shaft 26. A second sprocket 211 is press-fitted to the crankshaft 21. A cam chain 27 is wrapped about the first sprocket 261 and the second sprocket 211. The cam shaft 26 is configured to be driven when rotation of the crankshaft 21 is transmitted thereto through the cam chain 27.
The engine body 12 includes a cam chain compartment 121. The cam chain 27 is disposed in the cam chain compartment 121. The cam chain compartment 121 is disposed across the crankcase 13 and the cylinder unit 14. The cam chain compartment 121 is disposed in front of the cylinders 171. The cam chain compartment 121 is disposed between the power generator cover 25 and the cylinders 171.
Next, a lubrication system of the engine unit 1 will be explained.
The feed pump 32 is connected to a second oil path p2 through a check valve 321. The check valve 321 allows the lubricating oil to flow from the oil tank 33 to the second oil path p2. The check valve 321 prevents the lubricating oil from reversely flowing from the second oil path p2 to the oil tank 33. Further, a relief valve 36 is connected to the second oil path p2. The relief valve 36 is configured to be opened when the pressure of the lubricating oil within the feed pump 32 becomes a predetermined relief pressure or greater. When the relief valve 36 is opened, the lubricating oil within the feed pump 32 partially flows to the oil pan 16.
The second oil path p2 is connected to a main gallery 39 through an oil cooler 37 and an oil cleaner 38. The main gallery 39 is connected to oil paths provided inside the crankshaft 21. Further, the main gallery 39 is connected to a third oil path p3. The third oil path p3 is connected to oil paths provided inside the cam shaft 26. It should be noted that the camshaft 26 includes an exhaust camshaft 26a and an intake camshaft 26b. The third oil path p3 is connected to an oil path of the exhaust cam shaft 26a and that of the intake cam shaft 26b.
The oil paths provided inside the cam shaft 26 are connected to a fourth oil path p4. The fourth oil path p4 is connected to the oil path of the exhaust cam shaft 26a and that of the intake cam shaft 26b. The fourth oil path p4 is connected to the oil pan 16. The fourth oil path p4 will be explained below in detail.
In the engine unit 1 according to the present preferred embodiment, the lubricating oil is fed to the second oil path p2 from the oil tank 33 by the feed pump 32. The lubricating oil is further fed from the second oil path p2 to the main gallery 39 through the oil cooler 37 and the oil cleaner 38.
The lubricating oil is partially supplied from the main gallery 39 to journals of the crankshaft 21 through the oil paths provided inside the crankshaft 21. Further, the lubricating oil is supplied from the oil paths provided inside the crankshaft 21 to the pistons 172 (see
The lubricating oil is partially fed from the main gallery 39 to the oil paths provided inside the cam shaft 26 through the third oil path p3. The lubricating oil is supplied to journals of the cam shaft 26 through the oil paths provided inside the cam shaft 26.
The oil, supplied to the respective elements disposed inside the engine body 12 as described above, flows through the interior of the cylinder head 18 or that of the crankcase 13 and returns to the oil pan 16. Further, a surplus amount of lubricating oil inside the cam shaft 26 flows through the fourth oil path p4 and returns to the oil pan 16. The lubricating oil is returned from the oil pan 16 to the oil tank 33 by the scavenging pump 31.
As shown in
The pump drive mechanism 41 is disposed in an intermediate portion of the fourth oil path p4. Thus, the pump drive mechanism 41 is lubricated by the lubricating oil flowing through the fourth oil path p4. It should be noted that the pump drive mechanism 41 is not limited to a chain, and alternatively, may be another member. For example, the pump drive mechanism 41 may be a gear.
Next, a structure of the oil tank 33 will be explained in detail. As shown in
As shown in
The first component 43 is a discrete element separate from the tank body 42. The first component 43 is preferably a plate shaped member, for example. The first component 43 is joined to the tank body 42. When described in detail, the first component 43 is joined to the rear surface of the first body portion 45. The rear surface of the first body portion 45 opens horizontally. The first component 43 is joined to the first body portion 45, and thus, covers the opening in the rear surface of the first body portion 45.
The bottom surface of the first body portion 45 opens downwardly. The top surface of the second body portion 46 opens upwardly. The cylinder unit 14 is joined to the crankcase 13, and thus, the first body portion 45 is joined to the second body portion 46. With this structure, the second body portion 46 covers the opening in the bottom surface of the first body portion 45. In turn, the first body portion 45 covers the top surface of the second body portion 46.
The second component 44 is a discrete element separate from the tank body 42. The second component 44 is preferably integrally molded with the oil pan 16. The oil pan 16 is joined to the crankcase 13, and thus, the second component 44 is joined to the tank body 42. When described in detail, the second component 44 is joined to the bottom surface of the second body portion 46. The bottom surface of the second body portion 46 opens downwardly. The second component 44 covers the opening in the bottom surface of the tank body 42.
As shown in
The first joint surface s1 between the tank body 42 and the first component 43 extends in the first direction different from that of a third direction in which a third joint surface s3 between the first body portion 45 and the second body portion 46 extends. The first joint surface s1 is located above the third joint surface s3. When described in detail, the third direction of the third joint surface s3 is horizontal or substantially horizontal. Therefore, the first direction of the first joint surface s1 is orthogonal or substantially orthogonal to that of the third joint surface s3.
As shown in
The bottom wall 57 is disposed between the upper oil chamber 51 and the lower oil chamber 52. The bottom wall 57 divides the upper oil chamber 51 and the lower oil chamber 52.
As shown in
The first body portion 45 includes a portion 64 (hereinafter referred to as a first pump connection path 64) in the above described first oil path p1. The first pump connection path 64 is connected to the first chamber 61. It should be noted that, as shown in
The second chamber 62 is located laterally of the first chamber 61. The second chamber 62 communicates with the first chamber 61 through a communication path 65. The width of the communication path 65 is preferably narrower than the up-and-down directional width of the first chamber 61. The guide plate 58 includes a tilt portion 581. The tilt portion 581 divides the second chamber 62 and the third chamber 63. The tilt portion 581 is located under the second chamber 62. The tilt portion 581 tilts downwardly to a lateral side.
The first body portion 45 includes a first connection port 66 and a second connection port 67. The first connection port 66 and the second connection port 67 communicate with the upper oil chamber 51. The first connection port 66 is connected to a separator (not shown in the drawings). The second connection port 67 is connected to the above described head cover 15. The first connection port 66 and the second connection port 67 are located above the second chamber 62. The first connection port 66 and the second connection port 67 are preferably aligned in the right-and-left direction.
The first body portion 45 includes a first partition 68, a second partition 69, and a third partition 70. The first partition 68 divides the second chamber 62 and the first connection port 66. The second partition 69 divides the first connection port 66 and the second connection port 67. The third partition 70 divides the second connection port 67 and the communication path 65. The second chamber 62 and the space in which the first connection port 66 is disposed communicate through a first gap g1. The second chamber 62 and the space in which the second connection port 67 is disposed communicate through a second gap g2.
The third chamber 63 is located below the first chamber 61 and the second chamber 62. The third chamber 63 communicates with the second chamber 62 through a third gap g3. The first body portion 45 includes an opening 71. The opening 71 is preferably bored, for example, in the third chamber 63. The opening 71 extends in the back-and-forth direction and communicates with the interior of the crankcase 13. The opening 71 is closed by a lid member 72. The above described bottom wall 57 is disposed below the third chamber 63. As shown in
As shown in
The lubricating oil, existing inside the oil pan 16, is fed to the first oil path p1 by the scavenging pump 31. The lubricating oil is fed to the first chamber 61 through the first pump connection path 64. The lubricating oil is fed from the first chamber 61 to the second chamber 62 through the communication path 65. The lubricating oil flows along the tilt portion 581 in the second chamber 62 and is fed to the third chamber 63. The lubricating oil is fed from the third chamber 63 to the lower oil chamber 52 through the apertures 571 of the bottom wall 57. The lubricating oil is sucked from the lower oil chamber 52 into the feed pump 32 through the second pump connection path 73 and is fed to the second oil path p2 by the feed pump 32.
As shown in
When described in detail, the coupling shaft 22 overlaps with the oil tank 33 in the side view. Further, the coupling shaft 22 is supported by the oil tank 33 through the bearings 81 and 82. The coupling shaft 22 extends rearwardly from the engine body 12 to a position beyond the oil tank 33.
As shown in
The above described upper oil chamber 51 is located above the power transmission shaft 11. The lower oil chamber 52 is located under the power transmission shaft 11. The power transmission shaft 11 is partially disposed between the upper oil chamber 51 and the lower oil chamber 52. The power transmission shaft 11 is supported by the bottom surface of the upper oil chamber 51 and the top surface of the lower oil chamber 52. The power transmission shaft 11 is supported by the bottom surface of the upper oil chamber 51 and the top surface of the lower oil chamber 52 through the bearings 81 and 82.
The bottom wall 57 includes an upper recess 84 having an upwardly recessed shape. The upper recess 84 includes slopes 841 and 842 corresponding to the shape of the power transmission shaft 11. When described in detail, the upper recess 84 has a circular-arc or substantially circular-arc shape corresponding to the shape of the power transmission shaft 11. The space inside the upper recess 84 is divided from the upper oil chamber 51.
The upper surface of the second body portion 46 includes a lower recess 85 having a downwardly recessed shape. The lower recess 85 has a circular-arc or substantially circular-arc shape corresponding to the shape of the power transmission shaft 11. The space inside the lower recess 85 is divided from the lower oil chamber 52. The power transmission shaft 11 is disposed between the upper recess 84 and the lower recess 85. In other words, the above described through hole 83 is defined by the upper recess 84 and the lower recess 85.
In the vehicle 100 according to the preferred embodiments explained above, the oil tank 33 is preferably configured by joining the tank body 42, the first component 43, and the second component 44, which are discrete elements provided separate from each other. Further, the first joint surface s1 between the tank body 42 and the first component 43 extends in the first direction different from that of the second direction in which the second joint surface s2 between the tank body 42 and the second component 44 extends. Therefore, when fabricating the tank body 42 preferably by die casting, draft angles are provided on the tank body 42 in a plurality of directions.
When described in detail, a draft angle is provided on the first body portion 45 of the tank body 42 with respect to the back-and-forth direction. On the other hand, a draft angle is provided on the second component 44 with respect to the up-and-down direction. Thus, compared to when a draft angle is provided on the entire oil tank 33 only in one direction (e.g., the up-and-down direction), for instance, the thickness of the oil tank 33 according to the preferred embodiments of the present invention is further reduced. Consequently, a large oil storage space is provided inside the oil tank 33.
Further, the first body portion 45 and the second body portion 46 are discrete elements, and the first body portion 45 and the second body portion 46 open in different directions. Thus, when fabricating the first body portion 45 and the second body portion 46 preferably by die casting, different directional draft angles are respectively provided on the first body portion 45 and the second body portion 46. When described in detail, a draft angle is provided on the first body portion 45 with respect to the back-and-forth direction. On the other hand, a draft angle is provided on the second body portion 46 with respect to the up-and-down direction. Thus, compared to when a draft angle is provided on the entire tank body 42 only in one direction, the thickness of the tank body 42 is further reduced.
Further, the opening of the second body portion 46 is covered with the first body portion 45. Thus, the first component 43 is joined to the first body portion 45 without being joined to the second body portion 46. Since the second body portion 46 opens in the same direction as the first body portion 45, it is necessary to provide a structure to close both of the opening of the first body portion 45 and that of the second body portion 46 with the first component 43. In this case, the first component 43 requires high positional accuracy for the second body portion 46 as well as for the first body portion 45. Hence, it is difficult to manufacture the first component 43. However, in the present preferred embodiment, the first component 43 is joined to the first body portion 45 without being joined to the second body portion 46. Hence, it is easy to manufacture the first body portion 45, the second body portion 46, and the first component 43.
Elements disposed inside the first body portion 45, including the guide plate 58, the partitions 68 to 70, and the first pump connection path 64 of the first oil path p1, extend in the back-and-forth direction that is the same as the opening direction of the first body portion 45. Hence, when molding the first body portion 45 preferably by die casting, the above described elements are integrally configured. It is thus easy to manufacture the first body portion 45.
Preferred embodiments of the present invention have been explained above. However, the present invention is not limited to the above described preferred embodiments, and a variety of changes can be made without departing from the scope of the present invention.
In the above described preferred embodiments, the vehicle 100 preferably is a jet propelled watercraft, for example. However, the vehicle of the present invention is not limited to a jet propelled watercraft. Further, the vehicle according to the present invention is not limited to a water vehicle, and may be another type of vehicle such as an ATV (All Terrain Vehicle), a snowmobile, or a motorcycle. Alternatively, the jet propelled watercraft is not limited to the PWC as described in the above preferred embodiments, and may be another type of water vehicle such as a jet boat.
The orientation of the engine unit 1 is not limited to that described in the above preferred embodiments. For example, the orientation of the engine unit 1 may be reversed in the back-and-forth direction from that described in the above preferred embodiments. Alternatively, the engine unit 1 may be disposed such that the axis of the crankshaft 21 is oriented in the right-and-left direction of the vehicle.
In the engine unit according to the above preferred embodiments, the term “lateral” does not necessarily mean a direction matched with the right-and-left direction of the vehicle equipped with the engine unit. In the engine unit according to a preferred embodiment of the present invention, the term “lateral” may mean any direction in the horizontal or substantially horizontal direction.
The structure or the positional arrangement of the oil tank 33 is not limited to that described in the above preferred embodiments, and may be changed. For example, the oil tank 33 may be a discrete element separate from the engine body 12. The tank body 42 may not be divided into the first body portion 45 and the second body portion 46. The second component 44 may be a discrete element separate from the oil pan 16. The oil tank 33 may be disposed so as not to overlap with the power transmission shaft 11 in a side view.
The fourth oil path p4 may be disposed in a position different from that described in the above preferred embodiments. The fourth oil path p4 may be separate from the oil tank 33.
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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2014-148123 | Jul 2014 | JP | national |
Number | Name | Date | Kind |
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8316815 | Negoro | Nov 2012 | B2 |
20100044136 | Suzuki | Feb 2010 | A1 |
20130333980 | Tsunashima | Dec 2013 | A1 |
Number | Date | Country |
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09-317431 | Dec 1997 | JP |
Number | Date | Country | |
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20160017840 A1 | Jan 2016 | US |