Referring now to the attached drawings which form a part of this original disclosure.
Selected embodiments of the present invention will now be explained with reference to the drawings. It will be apparent to those skilled in the art from this disclosure that the following descriptions of the embodiments of the present invention are provided for illustration only and not for the purpose of limiting the invention as defined by the appended claims and their equivalents.
Referring initially to
The variable valve timing mechanism 1 is rotatably supported by a cam bracket (only partially shown in
The variable valve timing mechanism 1 is provided with a drive shaft 2 having a plurality of eccentric drive-shaft parts 3 (only one shown) that are press-fitted or otherwise affixed to the drive shaft 2. Thus, these eccentric drive-shaft parts 3 rotate integrally with the drive shaft 2. The drive shaft 2 extends in the cylinder-row direction and supported above intake valves 5 by the cam bracket (not shown). An arm-shaped first linkage 4 is also provided on the drive shaft 2 at each of the eccentric drive-shaft parts 3. The first linkage 4 operatively connects the eccentric drive-shaft part 3 of the drive shaft 2 to one end of a rocker arm 6.
In particular, the first linkage 4 is linked to one end part of the rocker arm 6 via a linking pin (not shown), and a second linkage 8 is linked to the other end part of the rocker arm 6 via a linking pin 7. The second linkage 8 operatively links the other end part of the rocker arm 6 to an oscillating cam 9 that is oscillatably attached to the drive shaft 2. The oscillating cam 9 contacts an upper surface of a tappet (valve lifter) 10 to move an intake valve 5 according to the oscillation position of the oscillating cam 9. A pair of intake valves 5 is preferably provided in each cylinder of the engine.
The variable valve timing mechanism 1 is mechanically linked a crankshaft (not shown) for varying lift amount and operating angle to open and close the intake valves 5 (only two shown). Thus, the variable valve timing mechanism 1 is configured to continuously change the lift characteristics, i.e., both the amount of valve lift and the operating angle, of the intake valves 5 according to the rotation of a control shaft 12. The control shaft 12 is rotatably supported by the same cam bracket above the drive shaft 2. The control shaft 12 is positioned parallel to the drive shaft 2.
The second linkage 8 and the tip part of the oscillating cam 9 are linked by a linking pin 17. A base-circle surface that forms an arc concentric with the drive shaft 2, and a cam surface that extends from the base-circle surface and defines a prescribed curve, are formed continuously on the bottom surface of the oscillating cam 9. The base-circle surface and the cam surface face contact the upper surface of a tappet (valve lifter) 10 according to the oscillation position of the oscillating cam 9. Specifically, when the oscillating cam 9 oscillates, and the cam surface contacts the tappet 10, with the base-circle interval of the base-circle surface being such that the lift amount is 0, the intake valve 5 will be pressed down against the counter force of the valve spring and will slowly begin to lift.
An eccentric control shaft part 18 is press-fitted or otherwise affixed to the control shaft 12 so that the eccentric control shaft part 18 rotates integrally with the control shaft 12. The rocker arm 6 is oscillatably supported by the eccentric control shaft part 18 as an intermediate member.
The drive shaft 2 is driven by the crankshaft of the engine via a timing chain or a timing belt (not shown). Thus, the drive shaft 2 rotates around an axis in response to the rotation of the crankshaft. The eccentric drive-shaft part 3 has a circular outer circumferential surface whose center is offset by a prescribed amount from the axis of the drive shaft 2. The substantially central part of the rocker arm 6 is oscillatably supported by the eccentric control shaft part 18. The eccentric control shaft part 18 is offset by a prescribed amount from the axis of the control shaft 12. The center of oscillation of the rocker arm 6 therefore changes according to the angular position of the control shaft 12.
The control shaft 12 is configured to rotate within a prescribed range of rotational angles via a control shaft actuator 13 provided at one end of the control shaft 12. The control shaft actuator 13 can also be referred to as an electromotive device in the illustrated embodiment. The control shaft actuator 13 is controlled by a controlling device 19. The control shaft actuator 13 is energized by electricity to apply a driving torque to rotate the control shaft 12 to a desired position for the desired valve lift characteristics. One the control shaft actuator 13 is deenergized, the control shaft 12 can be freely moved to a balanced or rest position as explained below.
There follows a brief description of the operation of the variable valve timing mechanism 1. When the drive shaft 2 rotates, the oscillating cam 9 oscillates via the eccentric drive-shaft part 3, the first linkage 4, the rocker arm 6, and the second linkage 8. The tappet 10 is pressed down by the oscillating cam 9, and the intake valve 5 is opened and closed against the spring force of the valve spring. When the angular position of the control shaft 12 is changed by the control shaft actuator 13, the initial position of the rocker arm 6 changes, and the valve lift characteristics of the oscillating cam 9 will change continuously. In other words, both the lift amount and the operating angle can be continuously and simultaneously enlarged or constricted. The results depend on the layout of the various parts, but the opening and closing times of the intake valve 5 will change, e.g., substantially symmetrically with the increases and decreases of the lift amount and the operating angle.
The drive shaft 2 and the control shaft 12 that extend in the cylinder-row direction are shared by the plurality of cylinders that constitute the cylinder row, whereas the oscillating cam 9, the rocker arm 6, the first linkage 4, the second linkage 8, and other structural components of the variable valve timing mechanism 1 (mechanism for varying lift and operating angle) are provided independently to each of the cylinders that constitute the cylinder row.
A flange part 24 is formed on the control shaft 12 of the variable valve timing mechanism 1. The flange part 24 acts as a flange-shaped rotating part on the control-shaft side. The flange part 24 protrudes from the outer circumferential surface of the control shaft 12, and regulates the movement of the control shaft 12 in the axial direction, as shown in
A substantially arc-shaped stopper protruding strip 26 is formed on the outer circumference of the flange part 24, protrudes radially outward from the control shaft, and mechanically regulates the range of rotation of the control shaft 12. The stopper protruding strip 26 has the same thickness along the axial direction of the control shaft 12 as the flange part 24. The stopper protruding strip 26 is formed so as to contact a stopper protruding-strip receiving surface 25b, which is the upper surface of the flange receiving part 25, in concert with the rotation of the control shaft 12. In other words, the stopper protruding strip 26 and the stopper protruding-strip receiving surface 25b constitute a stopper mechanism for mechanically stopping or locking the control shaft 12 at the upper and lower limit positions of the allowed range of rotation of the control shaft 12. Specifically, the stopper protruding strip 26 comprises a pair of upright walls 27 and an outer circumferential wall 28 disposed between the upright walls 27. The upright walls 27 are perpendicular to the outer circumferential surface of the flange part 24. The upright walls 27 are capable of contacting the stopper protruding-strip receiving surface 25b in concert with the rotation of the control shaft 12. The outer circumferential wall 28 is an arc concentric with respect to the flange part 24 and connects the upper ends of the upright walls 27. Meanwhile, the stopper protruding-strip receiving surface 25b is formed so as to be aligned with a plane that passes through the axis of the control shaft 12 when the control shaft is mounted on the upper surface of the cam bracket. The mechanically allowed range of rotation of the control shaft 12 is regulated by one of the upright walls 27 of the stopper protruding strip 26 contacting the stopper protruding-strip receiving surface 25b.
However, the range of controlled rotation of the control shaft 12 is set to be smaller than the mechanically allowed range of rotation for obtaining an actual target control value. In other words, the smallest limiting position of the mechanically allowed range of rotation (where one of the upright walls 27 of the stopper protruding strip 26 collides with the stopper protruding-strip receiving surface 25b) is set with leeway so as to have a smaller lift and operating angle than the minimum value of the target control value of the control shaft 12. In the same way, the largest limiting position of the mechanically allowed range of rotation (where the other upright wall 27 of the stopper protruding strip 26 collides with the stopper protruding-strip receiving surface 25b) is set with leeway so as to have a larger lift and operating angle than the maximum value of the target control value of the control shaft 12.
The control shaft actuator 13 of the present embodiment includes an electric motor 31, a ball-screw mechanism 32 and a linking mechanism 33. The electric motor 31 acts as a drive source. The ball-screw mechanism 32 is linked to the electric motor 31 for operating the ball-screw mechanism 32. The linking mechanism 33 links the ball-screw mechanism 32 to the control shaft 12, as shown in
The ball-screw mechanism 32 includes an elongated, cylindrical ball screw 34, a ball nut 35 and a plurality of balls 320. The ball screw 34 has a screw groove 34a formed on the outer circumferential surface, which is rotationally driven by the electric motor 31. The ball nut 35 has a screw groove 35a formed on the inner circumferential surface facing the screw groove 34a. The balls 320 are positioned between the screw groove 34a of the ball screw 34 and the screw groove 35a of the ball nut 35, as shown in
The linking mechanism 33 includes a first oscillating linkage 36 and a substantially L-shaped second oscillating linkage 37. The first oscillating linkage 36 is linked to the ball nut 35. The substantially L-shaped second oscillating linkage 37 has one end linked to the first oscillating linkage 36 and the other end affixed to the control shaft 12. The linking mechanism 33 changes the back-and-forth (linear) movement of the ball nut 35 into rotational movement that causes the control shaft 12 to rotate.
An intermediate-position holding mechanism 38 is provided within the control shaft actuator 13. The intermediate-position holding mechanism 38 is capable of holding the control shaft 12 in an intermediate position between the largest limiting position and the smallest limiting position that are the upper limit position and the lower limit position, respectively, of the mechanically allowed range of rotation.
The intermediate-position holding mechanism 38 includes a first spring member 39 and a second spring member 40. The first spring member 39 is arranged to constantly urge a first axial end of the ball nut 35 in a first axial direction of the ball screw (the right end in
In the variable valve timing mechanism 1 of the present embodiment, when the internal combustion engine stops, the driving torque of the electric motor 31 is no longer applied to the ball screw 34, the ball nut 35 is held in the balanced or rest position in which the urging force of the first spring member 39 and the urging force of the second spring member 40 are balanced. In other words, the control shaft 12 is held in the intermediate position (a position between the largest limiting position and the smallest limiting position of the mechanically allowed range of rotation of the control shaft 12) due to the ball nut 35 being held in the balanced position.
The first and second spring members 39 and 40 are both set so that the setting load is larger than the load necessary for the movement of the ball nut 35 when the control shaft 12 is changed from the upper limit position to the lower limit position of the allowed range of rotation of the control shaft.
The first and second spring members 39 and 40 are set so that the rotation angle position of the control shaft 12 when the ball nut 35 is in the balanced position has a lower lift and operating angle than the center of the usable range of operating angles of the intake valve 5 according to the variable valve timing mechanism 1. In other words, the lift characteristics of the variable valve timing mechanism 1 when the ball nut 35 is in the balanced position are set so that the lift and operating angle are smaller than the center of the range of usable operating angles of the intake valve 5.
When the ball nut 35 of the variable valve timing mechanism 1 of the present embodiment moves on the ball screw 34 toward the right in
As seen in
As described above, when the internal combustion engine stops, the driving torque of the electric motor 31 is no longer applied to the ball screw 34, the ball nut 35 is held in the balanced position by the intermediate-position holding mechanism 38. Also the intermediate-position holding mechanism 38 of the above mentioned embodiment is capable of holding the rotation angle position of the control shaft 12 in an intermediate position between the smallest limiting position and the largest limiting position of the mechanically allowed range of rotation of the control shaft 12. Therefore, if the held rotation angle position of the control shaft 12 is set to a lift amount and an operating angle that are appropriate for start-up, the rotation angle position of the control shaft 12 during idling need not be set at the start-up of the internal combustion since it has already been taken into account. The rotation angle position of the control shaft 12 can be set to a smaller lift amount and a smaller operating angle. The range of controlled rotation of the control shaft 12 can therefore be expanded in a relative manner toward a smaller lift and a smaller operating angle. Thus, the ability of the internal combustion engine to be started can be ensured, and the fuel consumption of the internal combustion engine can be improved.
The ball nut 35 is constructed to be urged by both the first and second spring members 39 and 40. Therefore rattling due to the unavoidable clearance of the ball-screw mechanism 32 can be prevented.
Part of the external force that is transmitted from the control shaft 12 to the ball nut 35 via the linking mechanism 33 can be supported by the urging forces of the first and second spring members 39 and 40 that are constantly acting on the ball nut 35. Therefore, when the ball nut 35 is held in a prescribed position for a target lift amount and target operating angle, the holding torque necessary for the electric motor 31 can be made relatively small, and the electric power usage of the electric motor 31 can be lessened.
The first and second spring members 39 and 40 are both set so that the setting load is larger than the load necessary for the movement of the ball nut 35 when the control shaft 12 is changed from the upper limit position to the lower limit position of the allowed range of rotation of the control shaft. Therefore, the holding force increases when the position of the ball nut 35 is held at that location, fluctuations in the lift and central angle of the intake valve 5 due to the load input from the intake valves 5 can be minimized, the load on the ball nut 35 from the first and second spring members 39 and 40 can be reduced when the ball nut 35 is moved on the ball screw 34 in concert with changes in the target lift amount and target operating angle of the variable valve timing mechanism 1, and the responsiveness of the variable valve timing mechanism 1 can be improved.
The lift characteristics of the variable valve timing mechanism 1 in the balanced position are set so that the lift amount and the operating angle are less than the center of the range of usable operating angles of the intake valve 5. The loss of torque from the electric motor 31 due to the friction of the first and second spring members 39 and 40 can therefore be reduced due to the fact that the normal range of the lift characteristics used by the variable valve timing mechanism 1 is usually within a region of a relatively small lift and operating angle. The lift characteristics of the variable valve timing mechanism 1 in the balanced position can be set in a center of the usable range of operating angles of the intake valve 5, but can also be set so that the lift and operating angle are greater than the center of the usable range of operating angles of the intake valve 5.
In the variable valve timing mechanism 1 described above, when the lift characteristics are changed to a relatively small lift and operating angle, i.e., when the ball nut 35 is made to move towards the right in
Referring now to
Basically, the variable valve timing mechanism 51 of the second embodiment has substantially the same configuration as the variable valve timing mechanism 1 of the above mentioned first embodiment. However, in the second embodiment, an intermediate-position holding mechanism 52 is positioned between the control shaft 12 and a cam bracket 53 on the upper part of the cylinder head. Thus, the intermediate-position holding mechanism 52 of the second embodiment is not provided within the housing of the control shaft actuator (not shown in
One end of the first spring member 54 has a first roller 56 affixed thereto. The other end of the first spring member 54 is affixed to a pillar part 60a that is fixed within a concave part 53a of the cam bracket 53. The first roller 56 is positioned on the outer circumference of the control shaft 12. The first roller 56 is positioned between a pair of first protruding walls 57 that protrude from the outer circumferential surface of the control shaft 12. The first roller 56 is rotatably supported by the first protruding walls 57. The pillar part 60a includes a substantially cylindrical protruding rod that extends parallel to the axial direction of the control shaft 12. The first spring member 54 has a coiled part that is externally disposed around the rod of the pillar part 60a.
One end of the second spring member 55 has a second roller 58 affixed thereto. The other end of the second spring member 55 is affixed to a pillar part 60b that is fixed within a concave part 53a of the cam bracket 53. The second roller 58 is positioned on the outer circumference of the control shaft 12. The second roller 58 is positioned between a pair of second protruding walls 59 that protrude from the outer circumferential surface of the control shaft 12. The second roller 58 is rotatably supported by the second protruding walls 59. The pillar part 60b includes a substantially cylindrical protruding rod that extends parallel to the axial direction of the control shaft 12. The second spring member 55 has a coiled part that is externally disposed around the rod of the pillar part 60b.
The rotation axes of the first and second rollers 56 and 58 are parallel to the axis of rotation of the control shaft 12. The urging forces of the first and second spring members 54 and 55 are balanced, i.e., equal in opposite directions to hold the control shaft 12 in a balanced position.
In the variable valve timing mechanism 51 of the second embodiment, when the internal combustion engine stops, the driving torque of the control shaft actuator 13 (not shown in
In the second embodiment as well as in the above mentioned first embodiment, the rotation angle position of the control shaft 12 can be held in the intermediate position between the smallest limiting position and the largest limiting position of the mechanically allowed range of rotation of the control shaft 12 when the internal combustion engine stops. Therefore, if the held rotation angle position of the control shaft 12 is set to a lift amount and an operating angle that are appropriate for start-up, then the rotation angle position of the control shaft 12 during idling need not be set during start-up of the internal combustion engine. The rotation angle position of the control shaft 12 can be set to a smaller lift and a smaller operating angle than when the rotation angle position of the control shaft 12 is at a center rotation angle position between largest limiting position and the smallest limiting position of the mechanically allowed range of rotation of the control shaft 12. The range of controlled rotation of the control shaft 12 can therefore be expanded in a relative manner toward a smaller lift and a smaller operating angle. In this way, the ability of the internal combustion engine to be started can be ensured, and the fuel consumption of the internal combustion engine can be improved.
The first and second spring members 54 and 55 are formed at the same position in the axial direction of the control shaft 12 in the second embodiment, but the first and second spring members 54 and 55 can also be positioned so as to be mutually offset in the axial direction of the control shaft 12. The control shaft 12 is configured to be urged directly by the first and second spring members 54 and 55 in the second embodiment. However, the spring members that directly urge the control shaft 12 are not limited to a single pair; e.g., the control shaft 12 can also be configured to be urged directly by two pairs of spring members.
Referring now to
The variable valve timing mechanism 61 of the third embodiment has substantially the same configuration as the above mentioned first embodiment, but in the third embodiment, the intermediate-position holding mechanism 62 is positioned between the flange receiving part 25 of the cam bracket and the stopper protruding strip 26 of the flange part 24 provided to the control shaft 12, and is not provided within the control shaft actuator 13 (not shown in
In other words, the intermediate-position holding mechanism 62 of the third embodiment also comprises the first and second spring members 63 and 64. The first spring member 63 directly urges the control shaft 12 in a first rotational direction toward the upper limit position of the allowed range of rotation of the control shaft 12. The second spring member 64 directly urges the control shaft 12 in a second rotational direction toward the lower limit position of the allowed range of rotation of the control shaft 12. In other words, the rotational directions urged by the first and second spring members 63 and 64 are mutually opposite rotational directions of the control shaft 12.
A first end of each of the first and second spring members 63 and 64 is affixed to one of the upright walls 27 of the stopper protruding strip 26, and a second end of each of the first and second spring members 63 and 64 is affixed to a corresponding one of the stopper protruding-strip receiving surfaces 25b. Specifically, the stopper protruding strip 26 includes a pair of protruding parts 65 with one protruding from each of the upright walls 27. The protruding parts 65 are inserted into the first ends of the first and second spring members 63 and 64, which are coil springs. Thus, the first ends of the first and second spring members 63 and 64 are affixed to the upright walls 27 of the stopper protruding strip 26. Each of the stopper protruding-strip receiving surfaces 25b includes a concave part 66. These concave parts 66 receive the second ends of the first and second spring members 63 and 64. Thus, the second ends of the first and second spring members 63 and 64 are affixed to the concave parts 66 of the stopper protruding-strip receiving surfaces 25b. The urging forces of the first and second spring members 54 and 55 are balanced, i.e., equal in opposite directions, to hold the control shaft 12 in a balanced position (i.e., the intermediate position).
In the variable valve timing mechanism 61 of the third embodiment, when the internal combustion engine stops, the driving torque of the control shaft actuator 13 (not shown in
In the third embodiment as well as in the above mentioned first and second embodiments, the rotation angle position of the control shaft 12 can be held in the intermediate position between the smallest limiting position and the largest limiting position of the mechanically allowed range of rotation of the control shaft 12 when the internal combustion engine stops. Therefore, if the held rotation angle position of the control shaft 12 is set to a lift amount and an operating angle that are appropriate for start-up. Thus, the rotation angle position of the control shaft 12 during idling need not be set during the start-up of the internal combustion engine. The rotation angle position of the control shaft 12 can be set to a smaller lift amount and a smaller operating angle than the center rotation angle position of the control shaft 12. The range of controlled rotation of the control shaft 12 can therefore be expanded in a relative manner toward a smaller lift and a smaller operating angle, the ability of the internal combustion engine to be started can be ensured, and the fuel consumption of the internal combustion engine can be improved.
The variable valve timing mechanisms 1, 51 and 61 of the above mentioned embodiments was applied to intake valves, but this variable valve timing mechanism can also be applied to exhaust valves. Thus, the term “intake/exhaust valve” is used generically to include either an intake valve or an exhaust valve.
Now some of the operational effects of the above embodiments will be explained.
By using the intermediate-position holding mechanism 38, 52 and 62, if the held rotation angle position of the control shaft 12 is set to a lift amount and an operating angle that are appropriate for start-up, the rotation angle position of the control shaft for idling need not be set during start-up of the internal combustion engine. Also the rotation angle position of the control shaft 12 can be set to a smaller lift amount and a smaller operating angle than the center rotation angle position of the control shaft 12. The range of controlled rotation of the control shaft can therefore be expanded in a relative manner toward a smaller lift amount and a smaller operating angle. Thus, the ability of the internal combustion engine to be started can be ensured, and the fuel consumption of the internal combustion engine can be improved.
In addition, when the control shaft actuator 13 includes a ball-screw mechanism 32 that is linked to a drive source, rattling due to the mechanistically unavoidable clearance of the ball-screw mechanism 32 can thereby be prevented. Part of the external force that is transmitted from the control shaft 12 to the ball nut 35 via the linking mechanism 36 can be supported by the urging forces of the first spring member 39 and the second spring member 40 that are constantly acting on the ball nut 35. Therefore, when the ball nut 35 is held in a prescribed position for a target lift amount and target operating angle, the holding torque necessary for the electric motor can be made relatively small, and the electric power usage of the electric motor can be lessened.
Moreover, the first and second spring members 39 and 40 are both set so that a setting load is larger than the load necessary for the movement of the ball nut 35 when the control shaft 12 is changed from the upper limit position to the lower limit position of the allowed range of rotation of the control shaft 12. Therefore, the holding force increases when the position of the ball nut 35 is held at that location. Also fluctuations in the lift and central angle of the intake valves can be minimized. Furthermore, the load on the ball nut 35 from the first and second spring members 39 and 40 can be reduced when the ball nut 35 is moved on the ball screw 34 in concert with changes in the target lift amount and target operating angle of the variable valve timing mechanism, and the responsiveness of the variable valve timing mechanism can be improved.
Also, when the balanced position is set so that, when the ball nut 35 is in the balanced position, the lift characteristics have a smaller lift and a smaller operating angle than the center of the usable range of operating angles of the engine valve. The loss of torque from the electric motor due to the friction of the first and second spring members 39 and 40 can thereby be reduced due to the fact that the normal range of lift characteristics used by the variable valve timing mechanism is usually within a region of relatively small lifts and operating angles.
While only selected embodiments have been chosen to illustrate the present invention, it will be apparent to those skilled in the art from this disclosure that various changes and modifications can be made herein without departing from the scope of the invention as defined in the appended claims. For example, the size, shape, location or orientation of the various components can be changed as needed and/or desired. Components that are shown directly connected or contacting each other can have intermediate structures disposed between them. The functions of one element can be performed by two, and vice versa. The structures and functions of one embodiment can be adopted in another embodiment. It is not necessary for all advantages to be present in a particular embodiment at the same time. Every feature which is unique from the prior art, alone or in combination with other features, also should be considered a separate description of further inventions by the applicant, including the structural and/or functional concepts embodied by such feature(s). Thus, the foregoing descriptions of the embodiments according to the present invention are provided for illustration only, and not for the purpose of limiting the invention as defined by the appended claims and their equivalents.
Number | Date | Country | Kind |
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2006-270233 | Oct 2006 | JP | national |
2007-185222 | Jul 2007 | JP | national |