1. Field of the Invention
The present invention relates to an engine, and more specifically to an engine having a variable valve mechanism arranged to switch a lift degree of a valve between a high speed state and a low speed state.
2. Description of the Background Art
JP 2002-303109 discloses a speed range selectable valve mechanism for an internal combustion engine. In this valve mechanism, a camshaft includes low and high cam noses, and a valve supported at a cylinder head is selectively engaged with one of the high and low cam noses by the cam-linkage, which allows the valve to be opened or closed according to the high and low speed ranges of the internal combustion engine. First and second rocker arms are pivotally supported at the cylinder head. The swinging end of the first rocker arm and the low cam nose are engaged with each other by the cam-linkage, and the swinging end of the second rocker arm and the high cam nose are engaged with each other by the cam-linkage. A columnar engaging member (connecting pin) is supported at the first rocker arm so that it can slide therein in a reciprocating manner. The engaging member slides and projects from the side of the first rocker arm to the side of the second rocker arm in such a manner that it can advance/withdraw. This allows the first and second rocker arms to be detachably engaged with each other. The cylinder head is provided with a hydraulic actuator that applies an external force upon the engaging member against the energizing force of an engagement releasing spring. The actuator includes a cylinder hole (hydraulic cylinder) formed at the cylinder head and a piston (hydraulic piston) snugly inserted into the cylinder hole so that the piston can slide in the hole in a reciprocating manner. The cylinder hole leads to the hydraulic pump through an oil passage. The oil passage is formed at the cylinder head. A coil-shaped rocker arm spring (lost motion spring) is fitted onto the pivotal shaft of the rocker arm and the spring urges the second rocker arm so that the second rocker arm and the high cam nose are engaged with each other by the cam-linkage.
The hydraulic actuator is provided between the valve springs in the valve mechanism but the spacing between the valve springs is small in a small size engine and therefore there is little free space. Since the cylinder hole (hydraulic cylinder) is formed at the cylinder head, it is difficult to form the cylinder holes with high precision in a multi-cylinder engine. It is also difficult to assemble the piston of the hydraulic actuator and the rocker arm. In addition, the complicated oil passage is difficult to form.
JP 10-18826 A discloses a variable mechanism capable of carrying out various kinds of switching about the opening/closing timing, the lift degree, and the stopping timing for intake or exhaust valves in an internal combustion engine. In the variable valve mechanism, five supports are attached in such locations that they hold the four cylinders among them, and a rocker shaft is inserted through these supports. One T-shaped low speed rocker arm is swingably provided at the rocker shaft for each cylinder. A camshaft is rotatably supported at each support, and a low speed cam used to swing the low speed rocker arm is provided at the camshaft. The variable valve mechanism includes a switching device used to switch the opening/closing timing and lift degree of a valve between two stages, i.e., the high speed state and the low speed state. The switching device includes a high speed rocker arm that is adjacent to the low speed rocker arm, swingably provided at the rocker shaft and does not directly push the valve, a high speed cam that swings the high speed rocker arm, and a hydraulic piston driving a switch pin that connects or disconnects the high speed rocker arm and the low speed rocker arm between each other.
However, the low speed rocker arm in the valve mechanism pushes two valves together in the same cylinder and therefore different lift degrees cannot be set for these valves. In addition, the low speed rocker arm is provided at the bore center and therefore the camshaft cannot be supported at the bore center. Therefore, the supporting rigidity of the camshaft is low and the valve mechanism is not suitable for high speed engines.
In order to overcome the problems described above, preferred embodiments of the present invention provide an engine having a camshaft with high supporting rigidity and a variable valve mechanism that can easily be assembled.
An engine according to a preferred embodiment of the present invention has a variable valve mechanism arranged to switch a lift degree of a valve between a low speed state and a high speed state and includes a cam carrier, a rocker shaft, a low speed rocker arm, a high speed rocker arm, and a switching device. The cam carrier includes a cam bearing portion and a rocker shaft support. The cam bearing portion is provided on a straight line passing through a bore center of a cylinder in a plane that is perpendicular or substantially perpendicular to a camshaft and supports the camshaft. The cam carrier is detachably provided at a cylinder head. The rocker shaft is arranged parallel or substantially parallel with the camshaft at the rocker shaft support. The low speed rocker arm is swingably supported by the rocker shaft and swings according to the low speed cam of the camshaft to push a stem end surface of the valve. The high speed rocker arm is swingably supported by the rocker shaft, aligned with the low speed rocker arm and swings according to the high speed cam of the camshaft. The switching device is arranged to disconnect the low speed rocker arm and the high speed rocker arm in the low speed state and connect the low speed rocker arm and the high speed rocker arm in the high speed state.
According to a preferred embodiment of the present invention, the cam bearing portion of the cam carrier is provided at the bore center, and not only the cam bearing portion but also the rocker shaft support that supports the rocker shaft is provided at the cam carrier, so that the supporting rigidity of the camshaft may be maintained highly while the engine may be easily assembled.
According to a preferred embodiment of the present invention, the low speed rocker arm includes a through hole arranged parallel or substantially parallel with the rocker shaft. The cam carrier further includes a hydraulic cylinder support. The switching device includes a connecting pin, a hydraulic cylinder, and a hydraulic piston. The connecting pin is slidably inserted into the through hole and urged toward the hydraulic cylinder support. The hydraulic cylinder is provided in the hydraulic cylinder support. The hydraulic piston is slidably inserted into the hydraulic cylinder and abutted against the connecting pin. The high speed rocker arm includes an engagement portion that is engaged with the connecting pin projecting from the through hole. The hydraulic cylinder may be snugly inserted into a hole arranged in the cam bearing portion, while the hole itself may be used as a hydraulic cylinder. More specifically, the hydraulic cylinder may be provided either separately from or integrally with the cam bearing portion.
In this way, the hydraulic cylinder and the hydraulic piston are provided in the cam bearing portion so that the engine can be reduced in size.
Other features, elements, steps, characteristics and advantages of the present invention will become more apparent from the following detailed description of preferred embodiments of the present invention with reference to the attached drawings.
Preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings, in which the same or corresponding elements are designated by the same reference characters, and their description will not be repeated.
The DOHC (Double Over Head Camshaft) engine according to a preferred embodiment of the present invention includes a variable valve mechanism that switches the lift degrees of the intake and exhaust valves between two stages, i.e., a low speed state and a high speed state. More specifically, with reference to
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High speed rocker arms 84 to 87 are swingably supported by the rocker shafts 48 to 51. The four high speed rocker arms 84 to 87 are provided corresponding to the four valves 22 and 24. The high speed rocker arms 84 to 87 are provided adjacent to the low speed rocker arms 80 to 83, respectively. The high speed rocker arms 84 and 85 swing according to the high speed cam 41 of the camshaft 40 on the intake side. The high speed rocker arms 84 and 85 do not directly push the intake valves 22. The high speed rocker arms 86 and 87 swing according to the high speed cam 41 of the camshaft 42 on the exhaust side. The high speed rocker arms 86 and 87 do not directly push the exhaust valves 24.
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The connecting pin 90 has a circular or substantially circular rim 96 at its head. The connecting pin 90 has the spring 98 wound therearound. The connecting pin 90 is slidably inserted into the through hole 88 from its bottom. The connecting pin 90 is therefore urged toward the hydraulic cylinder supports 43 and 45. The connecting pin 90 is longer than the through hole 88. Therefore, when the connecting pin 90 is thoroughly inserted into the through hole 88, the bottom of the connecting pin 90 projects from the opposite end of the through hole 88.
The hydraulic cylinder 92 is provided in each of the hydraulic cylinder supports 43 and 45. More specifically, a circular through hole 100 is arranged under each of the cutouts 54 and 56 of the cam bearing portions 44 and 46. The hydraulic cylinder 92 is snugly inserted into the through hole 100 and fixed in the hydraulic cylinder supports 43 and 45.
In this example, the through hole 100 of the hydraulic cylinder 92 is perforated in the hydraulic cylinder supports 43 and 45 and then the hydraulic cylinder 92 is inserted snugly into the through hole 100, while the through hole 100 itself may be used as a hydraulic cylinder without fitting any element in the through hole 100.
In addition, hydraulic pistons 94 on both sides are inserted into the hydraulic cylinders 92 inserted snugly in the common through holes 100 in this example, but two independent non-penetrating holes having different axial centers may be perforated from both sides of the hydraulic cylinder supports and then the hydraulic cylinders may be inserted into the non-penetrating holes. In this case, the hydraulic cylinders are aligned in the direction perpendicular or substantially perpendicular to the camshaft, so that the width of the hydraulic cylinder supports can further be narrowed.
The hydraulic piston 94 has a circular or substantially circular rim 102 at its head. The hydraulic piston 94 is slidably inserted into the hydraulic cylinder 92 from its bottom. The head (rim 102) of the hydraulic piston 94 is abutted against the head (rim 96) of the connecting pin 90.
In this way, the hydraulic cylinders 92 and the hydraulic pistons 94 are provided under the cam bearing portions 44 and 46, and therefore the switching device 89 can be compactly mounted in a small engine with a narrow inter-valve spring distance. In this example, as shown in
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The groove 120 is open to the side of the lower surface 116 and therefore it is easier to form the groove 120 rather than a hole. The groove 120 may be arranged at the upper surface 118 of the cylinder head 14 instead of at the lower surface 116 of the cam carrier 16. The groove 120 in this example is preferably straight, but it may be curved. It is easy to form grooves if their curves are complicated.
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In a high speed state, the OCV on the oil passage is opened to increase the oil pressure in the groove 120 and the hydraulic piston 94 is pushed to the outside. The connecting pins 90 are pushed accordingly and inserted into the through holes 88 of the low speed rocker arms 80 to 83. In this way, the bottoms of the connecting pins 90 are projected from the opposite ends of the through holes 88. The high speed rocker arms 84 to 87 are urged toward the high speed cam 41 by the lost-motion springs 108 and the engagement portions 104 are engaged with the connecting pins 90 projecting from the through holes 88. In this way, when the high speed rocker arms 84 to 87 are greatly swung according to the high speed cam 41 with a large displacement, the low speed rocker arms 80 to 83 are also greatly swung together with the high speed rocker arms 84 to 87. In response, the low speed rocker arms 80 to 83 push the intake or exhaust valves 22 and 24 by the stem end surfaces 79 and the intake or exhaust valves 22 and 24 are widely opened.
On the other hand, in a low speed state, the OCV on the oil passage is closed to decrease the oil pressure in the grooves 120 and the energizing force of the springs 98 pushes the connecting pins 90 back toward the hydraulic cylinder supports 43 and 45. In this way, the hydraulic pistons 94 are pushed into the hydraulic cylinders 92 and the bottoms of the connecting pins 90 are completely retained inside the through holes 88. Therefore, when the low speed rocker arms 80 to 83 are slightly swung according to the low speed cam 39 with a small displacement, the low speed rocker arms 80 to 83 push the intake or exhaust valves 22 and 24 by the stem end surfaces 79 and the intake or exhaust valves 22 and 24 are narrowly opened. At the time, the high speed rocker arms 84 to 87 are greatly swung according to the high speed cam 41, but the bottoms of the connecting pins 90 do not project from the through holes 88, and therefore the high speed rocker arms 84 to 87 do not push anything (idle movement).
According to this preferred embodiment, the cam bearing portions 44 and 46 are aligned on a straight line 55 passing through the bore center 53, and therefore the supporting rigidity of the camshafts 40 and 42 can be maintained in a high level. The cam bearing portions 44 and 46 as well as the rocker shaft support 52 is integral at the cam carrier 16 and after all the components are assembled to the cam carrier 16, the cam carrier 16 can be attached to the cylinder head 14, so that the assembling of the engine 10 can be easier.
The hydraulic cylinders 92 and the hydraulic pistons 94 are provided at the hydraulic cylinder supports 43 and 45 positioned under the cam bearing portions 44 and 46, and therefore the thickness D1 of the hydraulic cylinder supports 43 and 45 in the axial direction of the camshafts 40 and 42 can be larger than the distance D2 between the outer circumferences of the valve springs 26. Therefore, the hydraulic cylinders 92 and the hydraulic pistons 94 can be mounted compactly for a small engine with a narrow inter-valve spring distance.
The oil passage arranged to provide the hydraulic cylinders 92 with oil pressure is the groove 120 rather than a hole, and therefore the groove 120 can easily be formed by carrying out working of the lower surfaces 116 of the cam bearing portions 44 and 46. When die-casting is employed, the work for forming the groove is not necessary. The oil passage including the groove 120 can be simplified or shortened. Consequently, the variable valve mechanism can be reduced in size and the switching response can be improved.
Since the cam carrier 16 is arranged individually for each of the cylinders, holes for the rocker shafts 48 to 51 and the lost motion spring shaft 106 and the through hole 100 for the hydraulic cylinder 92 can be perforated for each cylinder, and various components can be assembled into the cam carrier 16 for each cylinder. In this way, the working/assembling to the cam carrier 16 is easily carried out and therefore large size equipment therefor is not necessary.
In a conventional variable valve mechanism in which the lost motion springs are wound around the rocker shafts, the low speed rocker arms, the high speed rocker arms and the lost motion springs occupy a large width in the axial direction and therefore the mechanism cannot be mounted in a small size engine. Stated differently, since the axial width is limited, the boss width of the rocker shaft portion of the rocker arm must be reduced. Therefore, the inclination of the rocker arm increases. In contrast, according to the preferred embodiments of the present invention, the axial center of the lost motion spring shaft 106 is outside the range defined by connecting the axial centers of the camshafts 40 and 42, the axial centers of the rocker shafts 48 and 50, and the midpoints of the stem end surfaces 79 of the valves 22 and 24. The lost motion springs 108 are wound around the lost motion spring shafts 106, not around the rocker shafts 48 and 50, so that the low speed rocker arms 80 to 83, the high speed rocker arms 84 to 87, and the lost motion springs 108 are less likely to interfere with one another. Therefore, the axial width occupied by these elements can be reduced and the structure can be compact and lightweight.
Furthermore, the rocker shaft support 52 has a projecting portion 124 projecting beyond the lower surfaces of the cam bearing portions 44 and 46, and the rocker shafts 48 to 51 are attached to the projecting portion 124. Therefore, if the connecting surface of the lower surfaces 116 of the cam carrier 16 and the upper surface 118 of the cylinder head 14 cannot be set low because of limitations such as the layout of the exhaust port 20, the height of the cylinder head 14 can be reduced by providing the rocker shafts 48 to 51 in a level lower than the connecting surface, so that the structure can be compact.
Since the low speed rocker arms 80 to 83, the high speed rocker arms 84 to 87, the connecting pin 90, the hydraulic piston 94 are provided for each of the intake or exhaust valves 22 and 24, different lift degrees can be set for the intake or exhaust valves 22 and 24.
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 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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2008-037656 | Feb 2008 | JP | national |
Number | Name | Date | Kind |
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5515820 | Sugimoto et al. | May 1996 | A |
6481398 | Uchiyama | Nov 2002 | B2 |
Number | Date | Country |
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0 258 061 | Mar 1988 | EP |
0 703 357 | Mar 1996 | EP |
1 247 945 | Oct 2002 | EP |
1 728 976 | Dec 2006 | EP |
2 230 818 | Oct 1990 | GB |
10-18826 | Jan 1998 | JP |
2002-303109 | Oct 2002 | JP |
2003-41915 | Mar 2003 | JP |
Number | Date | Country | |
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20090205598 A1 | Aug 2009 | US |