1. Field
Embodiments of the present invention relate to a water-jacket and water pump configuration in a water-cooled engine.
2. Description of the Related Art
A water-cooled engine is known from Japanese Patent Laid-Open No. 2005-009350 (Patent Document 1). Specifically, a water-cooling oil cooler is disposed on the front surface of the lower part of the engine main body mounted in a two-wheeled motor vehicle. A lead-in water path of the oil cooler is connected to an inlet conduit of a water pump disposed on the right sidewall of a cylinder body.
However, if the lead-in water path of the water-cooling oil cooler is connected to the inlet conduit of the water pump as disclosed in the above-mentioned Patent Document 1, a problem that the length of the pipework from the lead-in water path to the inlet conduit is long occurs depending on the arrangement positions of the water pump and the oil cooler to the engine main body.
The present invention is made in view of such circumstance and an object thereof is to provide a water-cooled engine that is so configured that the length of the pipework connected to a water-cooling oil cooler can be set short.
To achieve the above-described object, embodiments of the present invention provide a water-cooled engine in which a cylinder-body-side water jacket is formed in a cylinder body that is coupled to a crankcase rotatably supporting a crankshaft and has a cylinder bore. A cylinder-head-side water jacket is formed in a cylinder head coupled to the cylinder body. A water pump capable of making forced circulation of cooling water between the cylinder-body-side and cylinder-head-side water jackets and a radiator is disposed on an engine main body. The cylinder-body-side and cylinder-head-side water jackets are so formed that the cooling water is allowed to flow in the water jackets independently of each other. A first connection path, continuous with the cylinder-head-side water jacket connected to one of an inlet port and a discharge port of the water pump and a second connection path continuous with the cylinder-body-side water jacket connected to the other of the inlet port and the discharge port, are made in a sidewall of the cylinder body facing one side. A thermostat valve that makes switching between a state in which the first and second connection paths directly communicate with each other and a state in which the first and second connection paths are connected to each other via the radiator is attached to the sidewall of the cylinder body. A water-cooling oil cooler having a cooling water lead-in pipe for taking in the cooling water and a cooling water lead-out pipe for leading out the cooling water is so attached to one sidewall of the engine main body as to face the same direction as the direction of the thermostat valve. The cooling water lead-in pipe is so connected to the thermostat valve as to always communicate with the water jacket connected to the discharge port of the water pump, of the cylinder-body-side and cylinder-head-side water jackets, and the cooling water lead-out pipe is so connected to the thermostat valve as to always communicate with the water jacket connected to the inlet port of the water pump, of the cylinder-body-side and cylinder-head-side water jackets.
In another embodiment, a valve housing of the thermostat valve has an upstream chamber always communicating with the water jacket connected to the discharge port of the water pump, of the cylinder-body-side and cylinder-head-side water jackets, and a downstream chamber always communicating with the water jacket connected to the inlet port of the water pump, of the cylinder-body-side and cylinder-head-side water jackets, and is attached to the sidewall of the cylinder body. The cooling water lead-in pipe is connected via a first external conduit to an upstream connection pipe provided for the valve housing continuously with the upstream chamber, and the cooling water lead-out pipe is connected via a second external conduit to a downstream connection pipe provided for the valve housing continuously with the downstream chamber.
In another embodiment, the sidewall of the cylinder body is a front wall facing a front side in a state in which the engine main body is mounted on a vehicle. An attachment base for attaching the valve housing is formed on an outer surface of the front wall and the oil cooler is attached to a front wall of the crankcase below the thermostat valve.
In another embodiment, the radiator is disposed in front of the engine main body and the water pump is disposed more rearward than the cylinder body. A first connection port that is connected to one of the inlet port and the discharge port of the water pump and is continuous with the cylinder-head-side water jacket is provided in a rear wall of the cylinder head, and a second connection port that is connected to the other of the inlet port and the discharge port and is continuous with the cylinder-body-side water jacket is provided in a rear wall of the cylinder body.
In another embodiment, the thermostat valve is attached to the cylinder body with the actuation axis line of the thermostat valve set parallel to the axis line of the crankshaft, and the upstream connection pipe and the downstream connection pipe are so provided under the valve housing as to be arranged along the actuation axis line.
In another embodiment, the upstream connection pipe and the downstream connection pipe are so formed as to extend along a cylinder axis line.
In another embodiment, the thermostat valve and the oil cooler are so disposed as to partially overlap with each other when viewed from direction along the cylinder axis line.
In another embodiment, the plural cylinder bores arranged along the axis line of the crankshaft are formed in the cylinder body. A pair of lubricant return paths to return a lubricant from the cylinder head to the side of the crankcase via the cylinder body are formed in the front wall of the cylinder body with an interval along the arrangement direction of the cylinder bores. The thermostat valve and the oil cooler are disposed between the pair of lubricant return paths.
In yet another embodiment, the first connection path that is continuous with the cylinder-head-side water jacket and has a flattened cross-sectional shape that is long in direction along the axis line of the crankshaft is made in the front wall of the cylinder body in such a manner that a partition wall exists between the first connection path and the cylinder-body-side water jacket and the first connection path is disposed between the pair of lubricant return paths.
According to one embodiment of the present invention, the thermostat valve that makes switching between the state in which the first connection path continuous with the cylinder-head-side water jacket and the second connection path continuous with the cylinder-body-side water jacket directly communicate with each other and the state in which the first and second connection paths are connected to each other via the radiator is attached to the sidewall of the cylinder body. Furthermore, the water-cooling oil cooler is attached to the sidewall of the engine main body while facing the same direction as that of the thermostat valve. Moreover, the cooling water lead-in pipe of the oil cooler is so connected to the thermostat valve as to lead to the water jacket connected to the discharge port of the water pump, of the cylinder-body-side and cylinder-head-side water jackets, and the cooling water lead-out pipe of the oil cooler is so connected to the thermostat valve as to lead to the water jacket connected to the inlet port of the water pump, of the cylinder-body-side and cylinder-head-side water jackets. Due to this structure, the length of the pipework connected to the oil cooler can be set short.
According to another embodiment of the present invention, the valve housing of the thermostat valve is attached to the wall of the cylinder body. The cooling water lead-in pipe is connected via the first external conduit to the upstream connection pipe that is so provided for the valve housing as to communicate with the upstream chamber leading to the water jacket connected to the discharge port of the water pump, of the cylinder-body-side and cylinder-head-side water jackets. Furthermore, the cooling water lead-out pipe is connected via the second external conduit to the downstream connection pipe that is so provided for the valve housing as to communicate with the downstream chamber leading to the water jacket connected to the inlet port of the water pump, of the cylinder-body-side and cylinder-head-side water jackets. Thus, the following advantages are achieved compared with a structure in which the cooling water lead-in pipe and the cooling water lead-out pipe of the oil cooler are connected to a branch joint provided in the middle of the external pipework coupling the oil cooler to the radiator. Specifically, the first and second external conduits can be set short. Not only that but the branch joint in the middle of the pipework can be eliminated to simplify the pipework connection structure and the seal part can be reduced with ensuring of the arrangement flexibility of the cooling water lead-in pipe and the cooling water lead-out pipe.
According to another embodiment of the present invention, the thermostat valve is directly attached to the front wall of the cylinder body in the state in which the engine main body is mounted on the vehicle and the oil cooler is attached to the front wall of the crankcase. This can eliminate external pipework between the thermostat valve and the cylinder body and shorten the distance between the thermostat valve and the oil cooler to further shorten the first and second external conduits.
According to other embodiments of the present invention, the radiator is disposed in front of the engine main body and the water pump is disposed more rearward than the cylinder body. Furthermore, exchange of the cooling water between the cylinder-body-side water jacket and the cylinder-head-side water jacket and the water pump is carried out on the rear side of the engine main body. This can shorten the circulation route of the cooling water.
According to other embodiments of the present invention, the actuation axis line of the thermostat valve is parallel to the axis line of the crankshaft, and the upstream connection pipe and the downstream connection pipe are so provided under the valve housing of the thermostat valve as to be arranged along the actuation axis line of the thermostat valve. Thus, the directions of the external conduits between the thermostat valve and the oil cooler disposed below the thermostat valve can be aligned to shorten these external conduits.
According to other embodiments, the upstream connection pipe and the downstream connection pipe extend along the cylinder axis line. Therefore, the external conduits between the thermostat valve and the oil cooler can be disposed close to the front wall of the engine main body naturally. This can suppress size increase of the engine including these external conduits.
According to other embodiments, the thermostat valve and the oil cooler partially overlap with each other when viewed from the direction along the cylinder axis line. This can further shorten the distance between the thermostat valve and the oil cooler.
According to other embodiments, in the front wall of the engine main body configured as a multi-cylinder in-line engine, the pair of lubricant return paths to return the lubricant from the cylinder head to the side of the crankcase via the cylinder body are formed with an interval along the arrangement direction of the cylinder bores. Furthermore, the thermostat valve and the oil cooler are disposed between both the lubricant return paths. Thus, the thermostat valve and the oil cooler are effectively disposed in the space between both the lubricant return paths. This can suppress size increase of the engine and shorten the distance between the thermostat valve and the oil cooler.
According to other embodiment of the present invention, the first connection path continuous with the cylinder-head-side water jacket is so formed as to have a flattened cross-sectional shape that is long in the direction along the axis line of the crankshaft. Furthermore, the first connection path is made in the front wall of the cylinder body between the pair of lubricant return paths in such a manner that the partition wall exists between the first connection path and the cylinder-body-side water jacket. Therefore, the first connection path can be so disposed that interference with the lubricant return paths is avoided and frontward bulging of the front wall of the cylinder body is suppressed to avoid size increase of the engine main body.
Embodiments of the present invention will be described below with reference to accompanying
Referring first to
An engine main body 34 of a water-cooled engine E that is a four-cylinder engine is so mounted on the vehicle body frame F as to be located under the main frames 13. An axle 17 of a rear wheel WR driven to rotate by power output from this engine E is rotatably supported by the rear end part of a swing arm 19, and the front end part of this swing arm 19 is vertically swingably supported by the pivot frames 15 with the intermediary of a pivot shaft 18. A gear transmission (not shown) is included in the engine main body 34 and an endless chain 23 is wound around a drive sprocket 21 fixed to an output shaft 20 of the gear transmission and a driven sprocket 22 fixed to the axle 17.
A link mechanism 25 is provided between a cross pipe 24 coupling the lower parts of the pivot frames 15 to each other and the swing arm 19. A rear cushion unit 28 is provided between a link member 26 serving as part of the link mechanism 25 and a bracket 27 provided at the front part of the swing arm 19.
An air cleaner 30 is so disposed above the engine main body 34 as to be located behind the head pipe in the vehicle body frame F, and a fuel tank 31 covering the rear part and upper part of this air cleaner 30 is mounted on both main frames 13 in the vehicle body frame F. Behind the fuel tank 31, a main seat 32 for riding of the rider thereon is supported on the seat rails 16. A pillion seat 33 for riding of a fellow passenger thereon is supported by the seat rails 16 at a position separate from the main seat 32 rearward.
Referring to
Referring to
Intake ports 45 (see
In the cylinder body 38, a cylinder-body-side water jacket 50 is so formed as to surround the cylinder bores 43. A cylinder-head-side water jacket 51 is formed in the cylinder head 39. In addition, as shown in
As shown in
The water pump 54 is disposed more rearward than the cylinder body 38 and its pump housing 55 is more rearward than the cylinder body 38 and is fastened to the left sidewall of the lower case half body 36 in the crankcase 37 of the engine main body 34. In addition, part of the pump housing 55 is covered by a sprocket cover 56 that covers the drive sprocket 21 and is fastened to the left sidewall of the crankcase 37.
For the pump housing 55, an inlet pipe 59 that forms an inlet port 57 for drawing in the cooling water and a discharge pipe 60 that forms a discharge port 58 for discharging the cooling water are provided. The inlet port 57 is connected to one of the cylinder-body-side water jacket 50 and the cylinder-head-side water jacket 51, and the discharge port 58 is connected to the other of the cylinder-body-side water jacket 50 and the cylinder-head-side water jacket 51. In this embodiment, the inlet port 57 is connected to the cylinder-body-side water jacket 50 and the discharge port 58 is connected to the cylinder-head-side water jacket 51.
A first connection port 61 communicating with the cylinder-head-side water jacket 51 is provided in the rear wall of the cylinder head 39 and a second connection port 62 communicating with the cylinder-body-side water jacket 50 is provided in the rear wall of the cylinder body 38.
One end part of a first connection pipe 63 communicating with the first connection port 61 is fastened to the rear wall of the cylinder head 39 and the other end part of the first connection pipe 63 is connected to the discharge pipe 60 via a first hose 65. One end part of a second connection pipe 64 communicating with the second connection port 62 is fastened to the rear wall of the cylinder body 38 and the other end part of the second connection pipe 64 is connected to the inlet pipe 59 via a second hose 66.
The intermediate parts of the first and second hoses 65 and 66 are inserted in cylindrical hose support tubes 67 and 68 having rigidity and a holder 56a to hold both the hose support tubes 67 and 68 is formed integrally with the sprocket cover 56.
A starter motor 69 is disposed on the upper wall of the upper case half body 35 in the crankcase 37 behind the cylinder body 38 with its motor shaft 70 (see
Referring to
In the front wall 38a of the cylinder body 38, a pair of lubricant return paths 74, to return a lubricant from the cylinder head 39 to the side of the crankcase 37 via the cylinder body 38, are formed at positions separated along the arrangement direction of the cylinder bores 43 in such a manner as to vertically extend. The first connection paths 71 having a flattened cross-sectional shape that is long in the direction along the axis line of the crankshaft 42 are made in the front wall 38a of the cylinder body 38 in such a manner that a partition wall 75 exists between the first connection paths 71 and the cylinder-body-side water jacket 50 and the first connection paths 71 are disposed between the pair of lubricant return paths 74.
A water-cooling oil cooler 77 is so attached to one sidewall of the engine main body 34 as to face the same direction as that of the thermostat valve 73 and be disposed below the thermostat valve 73. In this embodiment, because the thermostat valve 73 is attached to the front wall 38a of the cylinder body 38, the oil cooler 77 is attached to a front wall 36a of the lower case half body 36 in the crankcase 37 below the front wall 38a of the cylinder body 38. In addition, the thermostat valve 73 and the oil cooler 77 are disposed between the pair of lubricant return paths 74.
A valve housing 80 of the thermostat valve 73 is composed of a housing main body 81 fastened to the attachment base 76 and a cap 82 liquid-tightly fastened to the housing main body 81.
Between the housing main body 81 and the cap 82, the outer circumferential part of a ring plate 84 having at its center part a first valve hole 83 having the center axis line along the axis line of the crankshaft 42, i.e. along the arrangement direction of the cylinder bores 43, is held. On the inner surface of the housing main body 81, a flange portion 86 extending inward is integrally formed with a second valve hole 85 coaxial with the first valve hole 83 made at the center part of the flange portion 86.
An upstream chamber 87 is formed between the ring plate 84 and the flange portion 86 in the valve housing 80. The upstream chamber 87 communicates with, via the first connection paths 71, the cylinder-head-side water jacket 51 connected to the discharge port 58 of the water pump 54 as one of the cylinder-body-side and cylinder-head-side water jackets 50 and 51. An intermediate chamber 88 is formed between the ring plate 84 and the cap 82 in the valve housing 80. In the cap 82, a lead-out connection pipe 89 for leading the cooling water of the intermediate chamber 88 to the side of the radiator 53 is provided. Furthermore, in the valve housing 80, a downstream chamber 90 is formed on the opposite side to the upstream chamber 87 across the flange portion 86. The downstream chamber 90 communicates with, via the second connection path 72, the cylinder-body-side water jacket 50 connected to the inlet port 57 of the water pump 54 as the other of the cylinder-body-side and cylinder-head-side water jackets 50 and 51. In the housing main body 81, a lead-in connection pipe 91 for taking in the cooling water from the radiator 53 into the downstream chamber 90 is provided.
In the intermediate chamber 88, a shaft support frame 92 that is so formed as to permit the flow of the cooling water and is provided continuously with the inner circumferential part of the ring plate 84 is so housed as to permit the flow of the cooling water. In the upstream chamber 87, a pair of spring bearing arms 93 that are provided continuously with the ring plate 84 and extend toward the opposite side to the shaft support frame 92 are disposed.
At the center part of the shaft support frame 92, one end part of a plunger 95 coaxially protruding from a movable portion 94 extending coaxially with the first and second valve holes 83 and 85 is fixedly supported. The movable portion 94 has a larger-diameter cylindrical portion 94a and a smaller-diameter cylindrical portion 94b in a coaxial manner and is formed into a stepped cylindrical shape. It can be filled, for example, with wax. Therefore, the other end part of the plunger 95 is inserted into the movable portion 94 from the side of the larger-diameter cylindrical portion 94a with the wax existing between the other end part and the movable portion 94.
A first valve body 96 that is seated on the inner circumferential part of the ring plate 84 and can close the first valve hole 83 is provided on the larger-diameter cylindrical portion 94a of the movable portion 94. A second valve body 97 that is seated on the inner circumferential part of the flange portion 86 and can close the second valve hole 85 is slidably supported on the smaller-diameter cylindrical portion 94b of the movable portion 94. A first spring 98 that biases the first valve body 96 toward the ring plate 84 is provided between the spring bearing arms 93 and the first valve body 96, and a second spring 99 that biases the second valve body 97 toward the flange portion 86 is provided between the movable portion 94 and the second valve body 97.
Such a thermostat valve 73 has the actuation axis line parallel to the axis line of the crankshaft 42. When the cooling water temperature is low, the first and second valve bodies 96 and 97 are actuated to such a side as to close the first valve hole 83 and open the second valve hole 85. In association with the rise of the cooling water temperature, the first and second valve bodies 96 and 97 are actuated to such a side as to open the first valve hole 83 and close the second valve hole 85.
Oil pumped up from the oil pan 41 by an oil pump (not shown) is led to the oil cooler 77 via an oil filter 100 (see
The cooling water lead-in pipe 101 of the oil cooler 77 is so connected to the thermostat valve 73 as to always communicate with the cylinder-head-side water jacket 51 connected to the discharge port 58 of the water pump 54. The cooling water lead-out pipe 102 is so connected to the thermostat valve 73 as to always communicate with the cylinder-body-side water jacket 50 connected to the inlet port 57 of the water pump 54.
Specifically, an upstream connection pipe 103 continuous with the upstream chamber 87, which always communicates with the cylinder-head-side water jacket 51 and is formed in the valve housing 80 of the thermostat valve 73, and a downstream connection pipe 104 continuous with the downstream chamber 90, which always communicates with the cylinder-body-side water jacket 50 and is formed in the valve housing 80, are provided for the housing main body 81 of the valve housing 80. The cooling water lead-in pipe 101 is connected to the upstream connection pipe 103 via a first external conduit 105 (for example, a hose) and the cooling water lead-out pipe 102 is connected to the downstream connection pipe 104 via a second external conduit 106 (for example, a hose).
In addition, the oil cooler 77 is disposed below the thermostat valve 73 and the upstream connection pipe 103 and the downstream connection pipe 104 are provided under the housing main body 81 in the valve housing 80 in such a manner as to be arranged along the actuation axis line of the thermostat valve 73 and extend along the cylinder axis line C.
Furthermore, under the housing main body 81, a water temperature detection sensor 107 arranged together with the upstream connection pipe 103 and the downstream connection pipe 104 along the actuation axis line of the thermostat valve 73 is so attached as to detect the water temperature in the upstream chamber 87.
Some effects of this embodiment will be described below. The cylinder-body-side and cylinder-head-side water jackets 50 and 51 are so formed that the cooling water is allowed to flow in the water jackets 50 and 51 independently of each other. The pair of first connection paths 71 continuous with the cylinder-head-side water jacket 51 connected to the discharge port 58 of the water pump 54 and the second connection path 72 continuous with the cylinder-body-side water jacket 50 connected to the inlet port 57 of the water pump 54 are made in the front wall 38a as a sidewall of the cylinder body 38 facing one side. The thermostat valve 73 that makes switching between the state in which the first and second connection paths 71 and 72 directly communicate with each other and the state in which the first and second connection paths 71 and 72 are connected to each other via the radiator 53 is attached to the front wall 38a. The water-cooling oil cooler 77 having the cooling water lead-in pipe 101 for taking in the cooling water and the cooling water lead-out pipe 102 for leading out the cooling water is so attached to one sidewall of the engine main body 34 as to face the same direction as that of the thermostat valve 73. The cooling water lead-in pipe 101 is so connected to the thermostat valve 73 as to always communicate with the cylinder-head-side water jacket 51, and the cooling water lead-out pipe 102 is so connected to the thermostat valve 73 as to always communicate with the cylinder-body-side water jacket 50. Due to this structure, the length of the pipework connected to the oil cooler 77 can be set short.
The valve housing 80 of the thermostat valve 73 has the upstream chamber 87 communicating with the cylinder-head-side water jacket 51 and the downstream chamber 90 always communicating with the cylinder-body-side water jacket 50 and is attached to the front wall 38a of the cylinder body 38. The cooling water lead-in pipe 101 of the oil cooler 77 is connected via the first external conduit 105 to the upstream connection pipe 103 provided for the valve housing 80 continuously with the upstream chamber 87, and the cooling water lead-out pipe 102 of the oil cooler 77 is connected via the second external conduit 106 to the downstream connection pipe 104 provided for the valve housing 80 continuously with the downstream chamber 90. Thus, the following advantages are achieved compared with a structure in which the cooling water lead-in pipe 101 and the cooling water lead-out pipe 102 of the oil cooler 77 are connected to a branch joint provided in the middle of the external pipework coupling the oil cooler 77 to the radiator 53. Specifically, the first and second external conduits 105 and 106 can be set short. Furthermore, the branch joint in the middle of the pipework can be eliminated to simplify the pipework connection structure and the seal part can be reduced with ensuring of the arrangement flexibility of the cooling water lead-in pipe 101 and the cooling water lead-out pipe 102.
The attachment base 76 for attaching the valve housing 80 is formed on the outer surface of the front wall 38a of the cylinder body 38 and the oil cooler 77 is attached to the front wall 36a of the crankcase 37 below the thermostat valve 73. This can eliminate external pipework between the thermostat valve 73 and the cylinder body 38 and shorten the distance between the thermostat valve 73 and the oil cooler 77 to further shorten the first and second external conduits 105 and 106.
The radiator 53 is disposed in front of the engine main body 34 and the water pump 54 is disposed more rearward than the cylinder body 38. The first connection port 61 that is connected to the discharge port 58 of the water pump 54 and is continuous with the cylinder-head-side water jacket 51 is provided in the rear wall of the cylinder head 39, and the second connection port 62 that is connected to the inlet port 57 of the water pump 54 and is continuous with the cylinder-body-side water jacket 50 is provided in the rear wall of the cylinder body 38. Thus, exchange of the cooling water between the cylinder-body-side water jacket 50 and the cylinder-head-side water jacket 51 and the water pump 54 is carried out on the rear side of the engine main body 34. This can shorten the circulation route of the cooling water.
The thermostat valve 73 is attached to the cylinder body 38 with its actuation axis line set parallel to the axis line of the crankshaft 42, and the upstream connection pipe 103 and the downstream connection pipe 104 are so provided under the valve housing 80 as to be arranged along the actuation axis line. Thus, the directions of the first and second external conduits 105 and 106 between the thermostat valve 73 and the oil cooler 77 disposed below the thermostat valve 73 can be aligned to shorten external conduits 105 and 106.
The upstream connection pipe 103 and the downstream connection pipe 104 are so formed as to extend along the cylinder axis line C. Therefore, the first and second external conduits 105 and 106 between the thermostat valve 73 and the oil cooler 77 can be disposed close to the front wall of the engine main body 34 naturally. This can suppress size increase of the engine E including these external conduits 105 and 106.
The thermostat valve 73 and the oil cooler 77 are so disposed as to partially overlap with each other when viewed from the direction along the cylinder axis line C. This can further shorten the distance between the thermostat valve 73 and the oil cooler 77.
The plural cylinder bores 43 arranged along the axis line of the crankshaft 42 are formed in the cylinder body 38. The pair of lubricant return paths 74 to return the lubricant from the cylinder head 39 to the side of the crankcase 37 via the cylinder body 38 are formed in the front wall 38a of the cylinder body 38 with an interval along the arrangement direction of the cylinder bores 43. The thermostat valve 73 and the oil cooler 77 are disposed between the pair of lubricant return paths 74. Thus, the thermostat valve 73 and the oil cooler 77 are effectively disposed in the space between both the lubricant return paths 74. This can suppress size increase of the engine E and shorten the distance between the thermostat valve 73 and the oil cooler 77.
The pair of first connection paths 71 that are continuous with the cylinder-head-side water jacket 51 and have a flattened cross-sectional shape that is long in the direction along the axis line of the crankshaft 42 are made in the front wall 38a of the cylinder body 38 in such a manner that the partition wall 75 exists between the first connection paths 71 and the cylinder-body-side water jacket 50 and the first connection paths 71 are disposed between the pair of lubricant return paths 74. Therefore, the first connection paths 71 can be so disposed that interference with the lubricant return paths 74 is avoided and frontward bulging of the front wall 38a of the cylinder body 38 is suppressed to avoid size increase of the engine main body 34.
Although embodiments of the present invention is explained above, the present invention is not limited to the above-described embodiments and various design changes can be made without departing from the present invention set forth in the scope of claims.
Number | Date | Country | Kind |
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2012-167427 | Jul 2012 | JP | national |