1. Field of the Invention
This invention relates to an engine valve train device for continuously controlling an opening duration or a lift of a valve.
2. Description of the Related Art
Conventionally, engine valve train devices for continuously controlling an opening duration and a lift of a valve have been in practical use. For example, there has been proposed such a valve train device in JP-A-Sho59-500002, in which, to open and close intake and exhaust valves by cam shafts via rocker arms, a swinging member for each valve is disposed and swung by the camshaft, an intermediate roller is interposed between a swing cam face of the swinging member and the rocker arm, and the valve opening duration and the valve lift can be continuously changed by displacing the intermediate roller.
Now, in such conventional valve train devices, the shorter the valve opening duration, the smaller the lever ratio of the rocker arm, and, in contrary, the longer the valve opening duration, the larger the lever ratio of the rocker arm. Due to the larger lever-ratio for a longer valve opening duration, a distal end of the rocker arm presses against the valve, and the intermediate roller presses against the intermediate portion of the rocker arm. As a result, it is difficult to secure rigidity of the entire valve opening/closing device. In particular, accuracy of control over the valve opening duration and the valve lift is apt to reduce during operation at high engine speeds. Further, due to a smaller lever-ratio for a shorter valve opening duration, it is difficult to secure the valve lift for a shorter valve opening duration, which is disadvantageous for reduction of pumping loss and improvement of combustibility. Thus, controllability of valve opening and closing timing is also apt to worsen.
Therefore, an object of the invention is to provide a valve train device that is rigid, provides accurate control of the valve lift for shorter valve opening duration, and provides the ability to continuously control the valve opening and closing timing.
Accordingly, one embodiment of the present invention comprises a valve train device of an engine for swinging a rocker arm, which is pivotally disposed on a rocker arm support shaft. The valve opens and closes a valve opening in a combustion chamber. The device comprises a drive device for driving the rocker arm, an intermediate member disposed between the drive device and the rocker arm and configured to transfer movement of the drive device to the rocker arm, and a displacement device. The displacement device includes a moveable portion that is coupled to an arm. A portion of the arm movies about a first axis. The displacement device is configured such that at least one of the valve opening duration and valve lift is increased as the moveable portion is displaced farther from the first axis.
Accordingly, another embodiment of the present invention comprises a valve train device of an engine for swinging a rocker arm, which is pivotally disposed on a rocker arm support shaft. The valve opens and closes a valve opening in a combustion chamber. The device comprises a drive device for driving the rocker arm and an intermediate member disposed between the drive device and the rocker arm and configured to transfer movement of the drive device to the rocker arm. The device also includes displacement means for displacing a contact point between the rocker arm and the intermediate member to continuously adjust at least one of the valve opening duration and valve lift where at least one of the valve opening duration or valve lift is increased as the contact point is displaced further from the rocker arm support shaft.
For purposes of summarizing the invention, certain aspects, advantages and novel features of the invention have been described herein. It is to be understood that not necessarily all such advantages may be achieved in accordance with any particular embodiment of the invention. Thus, the invention may be embodied or carried out in a manner that achieves or optimizes one advantage or group of advantages as taught herein without necessarily achieving other advantages as may be taught or suggested herein.
A general architecture that implements various features of specific embodiments of the invention will now be described with reference to the drawing. The drawing and the associated descriptions are provided to illustrate embodiments of the invention and not to limit the scope of the invention.
Several embodiments of the invention are described with reference to the accompanying drawings.
In the embodiments described below, reference will be made to the intake valve. However, it should be appreciated that certain features and aspects of these embodiments may also be applied to an exhaust valve. It should also be appreciated that various features, aspects and advantages of the present invent may be used with engines having more than one intake valve and/or exhaust valve, and any of a variety of configurations including a variety of numbers of cylinders and cylinder arrangements (V, W, opposing, etc.
Referring to
A valve train device 7 is disposed over the intake valves 3 and is constituted such that an intake camshaft 8, which functions as a swinging member driving device to swings each swinging member 9. The swinging member 9 swings a rocker arm 11 through an intermediate rocker 10, and the swinging movement of the rocker arm 11 forces the intake valve 3 to travel to and fro in its axial direction, thereby opening and closing the valve opening 2b.
The intake camshaft 8 is arranged parallel to a crankshaft (not shown), supported for rotation and prevented from moving in both of its axial direction and a direction normal to the axial direction, by cam journals formed in the cylinder head 2 and corresponding cam caps mounted on an upper mating surface of the cam journals. The intake camshaft 8 is formed with one cam nose 8c which is in common with the right and left intake valves and consists of a base circle section 8a having a constant outside diameter and a lift section 8b having a predetermined cam profile.
The swinging member 9 includes a pair of swing arm portions 9a, 9a, a swing cam face 9b, a roller shaft 9c, and swing roller 9d. The pair of swing arm portions 9a, 9a is supported for free rotation by a swing shaft 12 that is arranged parallel to the intake camshaft 8 and is prevented from moving in its axial direction and a direction normal thereto. The swing cam face 9b is formed so as to connect both the distal ends (lower ends) of the paired swing arm portions 9a, 9a. The roller shaft 9c is disposed midway of the swing arm portions 9a and parallel to the swing shaft 12 so as to pass through the right and left swing arm portions 9a, 9a. The swing roller 9d is supported for rotation by the roller shaft 9c, the swing roller 9d normally being in contact with the cam nose 8c for rotation.
The swing shaft 12 passes through the bases (upper end portion) of the swing arm portions 9a and swings. A pair of right and left balancing springs 13 of coil springs are mounted to the swing shaft 12. Each balancing spring 13 has a first end 13a that engages an edge positioned on the opposite side of the camshaft and between the roller shaft 9c and the swing shaft 12 of the swing arm portions 9a, and has a second end that engages the cylinder head 2. The paired balancing springs 13 bias the swinging member 9 so that the swing roller 9d contacts the cam nose 8c of the intake camshaft 8, to thereby avoid the weight of the swinging member 9 from acting on the valve spring 6.
The swing cam face 9b is generally shaped as a plate, having a curved surface in a base circle section 9e and a lift section 9f which are connected to each other continuously. The swinging member 9 is arranged in a way that the base circle section 9e is located on a rocker shaft side 14 and the lift section 9f is located on the opposite side thereof. The base circle section 9e is an arc having a radius R1 and a swinging axis (a) which is an axis of the swing shaft 12. Accordingly, while the base circle section 9e is in contact with the swing roller 9d and the swinging angle of the swinging member 9 increases, the intake valve 3 remains in its fully closed position and is not lifted.
On the other hand, as the point of the lift section 9f which presses against the swinging roller 9d progresses toward an apex of the lift section 9f and the swinging angle of the swinging member 9 becomes larger, the intake valve 3 is lifted more. The lift section 9f is constituted with a ramp zone for a constant velocity, an acceleration zone for acceleration of velocity, and a lift zone for an approximately constant velocity.
The rocker arm 11 is formed in one body such that it has a cylindrical base 11c, and right and left arm portions 11d extending forward (on the side of the intake valves). The base 11c is supported, for swing, by the rocker shaft 14 that is disposed parallel to the intake camshaft 8 and on the side of an axis of the cylinder. At the lower portion of the distal end of each arm portion 11d is formed a valve pressing face 11a so as to press against a shim 3c that is mounted to the upper end of a valve stem 3b of the intake valve 3. In an upper peripheral portion of each arm portion 1d is formed a pressurized rocker face 11b, which is pushed by a rocker pin 10a of the intermediate rocker 10. The pressurized rocker face 11b is formed into an arc having a radius R2 about the swinging axis (a) of the swinging member 9, as seen in the direction of the camshaft with the valve being fully closed.
The rocker shaft 14 is constituted so that the angular position of the rocker shaft 14 is freely controlled by a drive mechanism (not shown). Midway of the rocker shaft 14 is formed an eccentric pin portion 14a that has a diameter smaller than any other portions and deviated outwardly in a radial direction from the axis b of the rocker shaft 14. An engagement recess 10c formed in the base end of the intermediate arm portion 10b of the intermediate rocker 10 is rotationally engaged with the eccentric pin portion 14a.
The intermediate rocker 10 is generally configured such that both distal ends of the paired right and left intermediate arm portions 10b are fixedly connected to each other by the rocker pin 10a extending in the direction of the camshaft, and the rocker roller 10d is rotationally supported by the rocker pin 10a. The distal ends of the intermediate arm portions 10b may be coupled by engagement of the rocker pin 10a. The rocker roller 10d rotationally contacts the swing cam face 9b of the swinging member 9, and the rocker pin 10a slidably contacts the pressurized rocker face 11b of the rocker arm 11.
Thus, a displacing device is constituted such that the drive mechanism varies the angular position of the rocker shaft 14 to move or displace the positions of both the intermediate rocker roller 10d of the intermediate rocker 10 and the intermediate rocker pin 10a along the pressurized rocker face 11b.
A rocker lever ratio may be defined as Lv/Lc, where Lc is a distance between the swinging axis (b) of the rocker arm 11 and a straight line (A) which connects the swinging center (a) of the swinging member 9 and the point at which the swing cam face 9b contacts the intermediate rocker roller 10d; and Lv is a distance between the valve axis and the swinging center (b) of the rocker arm 11. The lever ratio increases as the opening duration of the valve becomes shorter.
The drive mechanism changes the angular position of the rocker shaft 14 to move or displace the positions of the intermediate rocker roller 10d and the intermediate rocker pin 10a of the intermediate rocker 10 along the swing cam face 96 and the pressurized rocker face 11b, causing the valve lift and the valve opening angle to change continuously. The drive mechanism controls the angular position of the rocker shaft 14 in such a manner that the valve opening angle and the valve lift increase as the valve opening increases in response to the opening of an acceleration pedal, for example.
Specifically, in
Meanwhile, in
In
In each lift curve of
In the embodiment, the swinging member 9 swings with the rotation of the camshaft 8, and the swinging of the swinging member 9 causes the swing cam face 9b to push against the intermediate rocker roller 10d, thereby oscillating the intermediate rocker member 10. Then, the intermediate rocker pin 10a of the intermediate rocker member 10 oscillates the rocker arm 11 to open and close the intake valve 3.
Subsequently, the rotation of the rocker shaft 14 continuously displaces the intermediate rocker roller 10d of the intermediate rocker member 10, the swing cam face 9b of the intermediate rocker pin 10a, and the contact point (c) with the pressurized rocker face 11b, which allows the valve opening duration and the valve lift to be controlled continuously.
Further, this embodiment is highly versatile, since there is no phase lag between the valve lift curves in the large and small opening durations. In other words, common mechanisms and components may be used for a right bank and a left bank of a V-engine.
Using the rotational motion of the rocker shaft 14 to move the intermediate rocker member 10, an extremely simple configuration can be obtained, resulting in an improvement of accuracy of control over the valve opening duration and the maximum valve lift.
For the purpose of displacing the contact point (c) using the rotational motion of the rocker shaft 14, a constitution is adopted that the base end of the intermediate rocker member 10 is swingably coupled with the eccentric pin portion 14a formed midway of the rocker shaft 14. The rotation of the rocker shaft 14 causes the intermediate rocker roller 10d and the intermediate rocker pin 10a to displace along the swing cam face 9b and the pressurized rocker face 11b. As a result, with an extremely simple constitution, the valve opening duration and the valve lift can be changed continuously.
A relative slide which occurs between the intermediate rocker pin 10a of the intermediate rocker member 10 and the pressurized rocker face 11b of the rocker arm 11 when the valve is opened and closed can be considerably reduced, since the rocker shaft 14 as the swinging axis of the rocker arm 11, and the eccentric pin portion 14a as the swinging axis of the intermediate rocker member 10 are positioned in proximity to each other.
Meanwhile, as shown in
On the other hand, in a small opening state in which both the valve opening duration and the maximum valve lift are small, as shown in
Further, the swing roller 9d is disposed within a space defined by lines connecting between the swinging center (a) of the swinging member 9 and both ends of the swing cam face 9b, as seen in the direction of the camshaft. As a result, bending moment generated due to a rotary force of the camshaft 8 at a portion for supporting the swing roller 9d can be caused to be smaller, compared with a conventional configuration in which a swing roller is supported at the distal end of a separate arm, for example, and the resultant rigidity of the swinging member is increased.
Furthermore, the balance springs 13 are provided for rotatably urging the swing member 9 in a direction that restricts the weight of the swing member 9 from working on the valve spring 6, which urges the valve in a closed state. Therefore, disposing the swing member 9 does not increase load on the valve spring 6. Thus, there is no need to increase the spring load of the valve spring 6, thereby providing optimum follow-up characteristics of the valve at high engine speed.
The second embodiment is an example in which the camshaft is of crankshaft type. That is, a crankshaft (camshaft) 18 includes a drive shaft 19a and a disk-like cam plate 19b, which is formed midway of the drive shaft 19a in one body and located eccentrically relative thereto. To the cam plate 19b is rotatably mounted a base 20a of a plate-like connecting rod 20, the distal end 20b of which is also rotatably coupled with a roller shaft 9c of the swinging member 9.
In the second embodiment, rotation of the drive shaft 19a eccentrically rotates the cam plate 19b about the axis (d). The connecting rod 20 oscillates the swinging member 9, and this swinging motion causes the rocker arm 11 to open and close the intake valve 3 through the intermediate rocker member 10.
In the second embodiment, since the camshaft is of a crankshaft type, it is possible to oscillate the swinging member 9 easily, securely with ability to follow exactly, the valve opening duration and the valve lift are controllable accurately, and any balancing spring is not needed.
The third embodiment is an example in which separate valve train devices 7, 7 are provided for the right and left intake valves 3, 3′, respectively. Specifically, it is constituted such that a left cam nose 8c and a right cam nose 8c′ oscillate a left swinging member 9 and a right swinging member 9′, respectively, which in turn oscillate a left rocker arm 11 and a right rocker arm 11′, respectively, which subsequently advance and retract the intake valves 3, 3′, respectively, to thereby open and close the intake valve openings 2b, 2b′.
In the third embodiment, since the left and right valve train devices 7, 7′ are separately disposed, an appropriate geometry of the left and right cam noses 8c, 8c′, left and right swing cam faces 9b, 9b′, and left and right intermediate rockers 10, 10′ allow the intake valves 3, 3′ to operate at different open and close timings as well as with different amounts of valve lift.
In this embodiment, the intermediate rocker 10 has an intermediate arm portion 10b, the base end of which is bifurcated and fitted in an eccentric pin portion 14a. An engagement pin 10g is passed through the bifurcated portion to shut the eccentric pin portion 14a. In such a way, the intermediate rocker 10 is rotationally coupled with a rocker shaft 14.
As described above, the rocker arm 11 is not pressed directly by the intermediate rocker pin 10a, but is pressed by the pressing face 10f that has a large curvature and is formed in the intermediate rocker 10. It is therefore possible to relax contact stress on the rocker pressing face and also to reduce the number of parts to be required.
In the embodiments described thusfar, it has been described that the swinging member 9 is supported by the swing shaft 12 and the rocker arm 11 is supported by the rocker shaft 14. However, in other embodiments, the swinging member 9 and the rocker arm 11 may be supported by a spherical pivot, respectively.
Also, it has been described that the drive device for swinging the swinging member 9 is a camshaft 8 or 18. However, the drive device is not limited to the camshaft. In other embodiments, any other type of driving devices, such as a solenoid type or a cylinder type that are capable of swinging the swinging member 9 in response to the engine speed may be used.
Further, in the embodiments described, the displacing device for the intermediate rocker 10 is of eccentric pin type that is incorporated in the rocker shaft 14. However, this displacing device is not limited to the eccentric pin type. Any other type of displacing device, such as a solenoid type or a cylinder type, may be used, which, in brief, are capable of displacing the intermediate rocker 10 so as to change the contact points between the rocker roller and rocker pin and the swing cam face and the pressurized rocker face.
The fifth embodiment is an example in which a roller 9d is attached to the swinging member 9 and rotationally contacts a cam nose 8c of a camshaft 8. A relative length Lc′ between an axis (d) of a roller shaft 9c of a roller 9d and an axis (a) of a swing shaft 12 of the swinging member 9 is variable. The roller 9d is guided by changing the relative length in the direction D, which is inclined relative to a straight line (E) connecting the axis (a) with the axis (d).
Specifically, a lever ratio. Lv/Lc′ of the swinging member when the valve opening duration is short is determined to be larger than that when the valve opening duration is long, where Lc′ is defined as a relative distance between the axis (a) of the swing shaft 12 of the swinging member 9 and the axis (d) of a camshaft abutment portion (roller) 9d of the swinging member 9 which contacts with the cam nose 8c, and Lv is defined as a distance between an axis (b) of a swing shaft 14 of the rocker arm 11 and the valve axis (B).
Midway of the swinging member 9 is formed a guide 9g which is an elongated slot through the swinging member 9. A roller shaft 9c is passed through the guide 9g and is displaceable in the direction D. The roller shaft 9c has an axis (d) parallel to the swing shaft 12 and supports the roller 9d for rotation.
The guide 9g is formed in shape of an elongated slot for guiding the roller shaft 9c to a predetermined distance in the longitudinal direction of the guide 9g. The guide direction (the axis of the guide) (D) is defined to be inclined relative to the straight line (E) which connects the axis (a) of the swinging member 9 and the axis (d) of the roller 9d. More specifically, the guide 9g is guided in a way that the larger the relative length Lc′ becomes (the more close to the state shown in
The swinging member 9 is provided with a roller (abutment portion) variable mechanism 30 for varying the relative length Lc′ of the roller 9d. The roller variable mechanism 30 includes a drive shaft 31 formed to have an axis (e) which is parallel to the axis (a) and positioned to be eccentric in a radial direction thereof and an arm 32 having one end 32a which is connected with the roller 9c and having the other end 32b which is coupled with a drive shaft 31 for rotation relative thereto. The other end 32b is formed to be bifurcated and provided with a pin 32c for preventing the drive shaft 31 from coming off.
Here, an actuator (not shown) for rotating the swing shaft 12 about the axis (a) is coupled with an outer, axial end of the swing shaft 12 and is connected to a control device for controlling an angular position of the swing shaft 12, in response to the engine speed or engine load.
In the range of an idling operation or low-speed, low-load operation, as shown in
As the engine speed and load become higher, as shown in
At this time, the roller 9d is brought into a left end position of the guide 9g, which is the nearest position from the camshaft 8, resulting in the longest relative length Lc′ and the smallest lever ratio (Lv/Lc′) of the swinging member. At this time, the roller 9d is positioned on the camshaft 8 side. The swinging member 9 therefore contacts the rocker roller 10 at a left end (as shown in the drawing) of a base circle section 9e of the swing cam face of the swing ember 9, resulting in the longest opening duration and the largest lift of the valve 3.
Also, in this embodiment, since a lever ratio Lv/Lc′ of the swinging member in the engine operation range of a short valve opening duration is determined to be larger than that in the engine operation range of a long opening duration, the same effects as described in
Further, since the roller variable mechanism 30 is constituted such that rotation of the swing shaft 12 of the swinging member 9 displaces the position of the drive shaft 31 and thus the position of the roller 9d, the relative distance between the roller 9d as a camshaft abutment portion and the swinging shaft 12 can be changed with a simple constitution.
Furthermore, since the longitudinal axis (D) of the elongated slot like guide 9g for guiding the roller 9d to the predetermined position is inclined relative to the straight line (E) of the swinging member 9, varying the relative distance Lc′ between the roller 9d and the swing shaft 12 also varies the valve lift and the valve opening duration. Appropriate settings of the inclination angle and inclination direction of the longitudinal axis (D) allow for optional selection of the valve lift and valve opening duration.
Since the abutment portion to the camshaft 8 is a roller 9d that contacts and rotates on the cam nose 8c of the camshaft 8, it is possible to reduce the loss of the driving force transmitted from the camshaft 8 to the camshaft abutment.
In the sixth embodiment, a rocker arm 11 serves as the swinging member in each embodiment described above, and an relative distance Lc″ between the rotation axis (d) of the roller 9d driven by the camshaft 8 and the swinging axis (b) of the rocker arm 11 is variable.
Specifically, the rocker arm 11 is supported by a swing shaft 14 and swung about a swinging axis (b). The rocker arm 11 is biased by a biasing spring (not shown) in clockwise direction as shown in the drawing, to thereby normally press a rocker pressing face against the roller shaft 9c, and press the roller 9d against a cam nose 8c of the camshaft 8. The rocker arm 11 is formed with a cam face consisting of a base circle section 9g which is a concentric circle whose center is the swinging center (b) and does not lift the valve 3 with increase of the swinging angle, and a lift section 9f for lifting the valve 3 with increase of the swinging angle of the rocker arm 11 in counterclockwise, as shown in the drawing. The cam face presses and drives the valve 3 via a valve lifter 4a that is disposed at the top end of the valve 3.
The rocker arm 11 is provided with a roller variable mechanism 30 for varying the relative distance Lc″. This roller variable mechanism 30 includes a drive shaft 31 that is formed at a position radially eccentric from the axis (b) of the swing shaft 14 and has an axis (e) parallel to the axis (b), and an arm 32 having one end 32a coupled with the roller shaft 9c and the other end 32b coupled with the drive shaft 31 for rotation relative thereto. The other end 32b is formed to be bifurcated and provided with a pin 32c for preventing the drive shaft 31 from coming off.
Here, an actuator (not shown) for rotating the swing shaft 14 about the axis (b) is coupled with an outer, axial end of the swing shaft 14 and is connected to a control device for controlling an angular position of the swing shaft 14, in response to the engine speed or engine load.
Now, a rocker lever ratio Lv/Lc″ when the valve opening duration is short, where Lc″ is a relative distance between the axis (b) of the swing shaft 14 of the rocker arm 11 and the axis (d) of the roller 9d, and when Lv is a distance between the axis (b) of the swing shaft 14 of the rocker arm 11 and the valve axis (B), is determined to be larger than that when the valve opening duration is large.
In the range of an idling operation or low-speed and low-load operation, as shown in
As the engine speed and load become higher, as shown in
By the way, during the intake stroke, the contact point of between the cam face of the rocker arm 11 and the valve lifter 4a is changed in its position such that the contact point is displaced from one side to the other side and subsequently returns from the other side to the one side of the valve axis (B). Accordingly, in this embodiment, the lever length (Lv) is defined as a distance between the valve axis (B) and the axis (b) of the rocker arm 11.
Thus, in this embodiment, since the rocker lever ratio Lv/Lc″ in the engine operation range of a short valve opening duration is determined to be larger than that in the engine operation range of a long opening duration, the same effects as described in
Further, since the roller variable mechanism 30 is constituted such that rotation of the swing shaft 14 of the rocker arm 11 displaces the position of the drive shaft 31 and thus the position of the roller 9d, the relative distance Lc″ can be changed with a simple constitution.
Since the camshaft abutment portion on the camshaft 8 is a roller 9d that contacts and rotates on the cam nose 8c of the camshaft 8, it is possible to reduce the loss of the driving force transmitted from the camshaft 8 to the camshaft abutment portion.
According to the embodiments described above it is more efficient to secure the valve lift since the lever ratio is determined to be larger when the valve opening duration is shorter. It is therefore possible to reduce pumping loss, improve combustibility, suppress reduction of the ramp velocity, and improve the ability to control the valve opening and closing timing.
According to another embodiment, when the swing shaft is swung by the driving device, the rocker arm is swung by the swing of the swing shaft via the intermediate rocker member to open and close the valve. The opening duration and the lift of the valve can be adjusted continuously, since the contact point between the pressurized rocker face and the swing cam face of the intermediate rocker member is forced to displace.
Additionally, according to another embodiment, an action to increase the valve lift in spite of a shorter opening duration of the valve, is achieved since the rocker lever ratio (Lv/Lc) is determined to be larger for a shorter opening duration of the valve. Also, as described above, the swinging member lever ratio (Lv/Lc′) is determined to be larger for a shorter opening duration of the valve, and the rocker lever ratio (Lv/Lc″) is determined to be larger for a shorter opening duration of the valve. It is therefore possible to reduce pumping loss, suppress reduction in the ramp velocity, and improve combustibility and ability to control the valve opening and closing timing.
Also, according to another embodiment, the contact point between the pressurized rocker face and the intermediate rocker member is positioned approximately just above the valve axis since the rocker lever ratio is determined to be smaller for a longer opening duration of the valve. It is also possible to increase the rigidity as a whole of the valve opening and closing mechanism.
According to another embodiment, the intermediate rocker roller and the intermediate rocker pin are provided at the distal end of the intermediate arm portion; the camshaft is located across the swinging member from the rocker shaft of the rocker arm; the swinging member is located such that the base circle section of the swing cam face is located on the rocker shaft side; and the rocker lever ratio becomes larger as the intermediate rocker roller and the intermediate rocker pin are moved toward the rocker shaft side, and, in contrast, it becomes smaller as they are moved away from the rocker shaft side. The locker lever ratio (Lv/Lc) for a shorter opening duration of the valve can be determined to be larger than that for a longer opening duration of the valve.
Further, according to another embodiment, the intermediate rocker roller and the intermediate rocker pin can be displaced toward or away from the rocker shaft side, using a simple configuration, to continuously control the valve opening duration and the valve lift, since a connection recess formed in the base end of the intermediate rocker member is engaged with the eccentric pin provided midway of the rocker shaft to rotate the rocker shaft.
According to another embodiment 5, since the camshaft may be of crankshaft type having a cam plate, and the cam plate and the swinging member are connected via the connecting rod, the swinging member can be securely and easily driven with sufficient ability to follow and oscillate easily, resulting in improvement of accuracy to control the valve opening duration and the valve lift.
According to another embodiment, the relative distance between the camshaft abutment portion and the swinging axis can be changed with a simple constitution of the abutment displacing mechanism which includes a drive shaft having its axis displaceable relative to the swinging axis of the swinging member or the rocker member, and an arm portion having one end coupled with the camshaft abutment portion and the other end coupled with the drive shaft.
According to another embodiment, a guide portion for guiding the camshaft abutment portion to a given position is inclined relative to the radial direction of the camshaft. The range of the combination of the valve lift and the valve opening duration can be therefore extended due to the variable relative distance between the camshaft abutment portion and the swinging shaft.
According to another embodiment, since the camshaft abutment portion is a roller that contacts and rotates on the camshaft, it is possible to reduce loss of the driving force transmitted from the camshaft to the camshaft abutment portion.
Although the foregoing systems and methods have been described in terms of certain preferred embodiments, other embodiments will be apparent to those of ordinary skill in the art from the disclosure herein. Additionally, other combinations, omissions, substitutions and modifications will be apparent to the skilled artisan in view of the disclosure herein. While certain embodiments of the inventions have been described, these embodiments have been presented by way of example only, and are not intended to limit the scope of the inventions. Indeed, the novel methods and systems described herein may be embodied in a variety of other forms without departing from the spirit thereof.
Number | Date | Country | Kind |
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2002-143037 | May 2002 | JP | national |
The present application is a continuation of PCT Application No. PCT/JP03/06202, filed on May 19, 2003, which claims priority under 35 U.S.C. § 119 to Japanese Patent Application No. 2002-143037, filed on May 17, 2002, and the entire contents of both of which are expressly incorporated by reference herein.
Number | Name | Date | Kind |
---|---|---|---|
4572118 | Baguena | Feb 1986 | A |
4714057 | Wichart | Dec 1987 | A |
5018487 | Shinkai | May 1991 | A |
5189998 | Hara | Mar 1993 | A |
5373818 | Unger | Dec 1994 | A |
6425357 | Shimizu et al. | Jul 2002 | B1 |
20010052329 | Himsel | Dec 2001 | A1 |
Number | Date | Country |
---|---|---|
6-93816 | Apr 1994 | JP |
6-307219 | Nov 1994 | JP |
11-36833 | Feb 1999 | JP |
2003-106123 | Apr 2003 | JP |
2003-239713 | Aug 2003 | JP |
Number | Date | Country | |
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20050126526 A1 | Jun 2005 | US |
Number | Date | Country | |
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Parent | PCT/JP03/06202 | May 2003 | US |
Child | 10990557 | US |