1. Field of the Invention
The present invention relates to a phase angle controller for controlling a phase angle between two rotary members. Particularly, the present invention is concerned with a phase changing device having a wide control range for realizing an optimum control position in a valve timing controller (hereinafter referred to as “VTC”) for an internal combustion engine which device makes variable an opening/closing timing of an intake valve or an exhaust valve actuated by an crank shaft through a cam shaft.
2. Description of the Related Art
First, a VTC used in an automobile engine will be outlined with reference to
Functions or effects attained by each VTC described above will be explained below with reference to
In
In
In
In various operating conditions of the valve timing controller, in both idling of “b.” and high-speed operation of “c.”, the intake valve timing is shifted to the delay side relative to the base position in the top stage to attain the effects shown in
Further, locking the VTC irrespective of position thereof at the time of start-up of the engine has heretofore been required because the VTC is unstable until ensuring a predetermined oil pressure after engine starting and there is a possibility that a beating noise may occur due to vibration or collision.
In view of this point there has heretofore been proposed an intermediate position locking mechanism in a VTC wherein a locked position in engine starting is set at an intermediate position (see, for example, Japanese Patent Laid-Open Publication No. 2001-241307). This intermediate position locking mechanism is based on the way of thinking that in connection with locking to the intermediate position by a vane-induced oil pressure, a stopper portion is formed only at the time of engine stop and starting during automatic return from an advance side to a most delayed position and a locking mechanism such as a locking pin is operated while the VTC is held temporarily on the stopper portion. In Japanese Patent Laid-Open Publication No. Hei 11(1999)-343819 is proposed an intermediate position locking mechanism wherein an automatic return to an intermediate locking position is to be made from not only an advance side but also a delay side.
However, in the related art, including Japanese Patent Laid-Open Publication No. 2001-241307 and Japanese Patent Laid-Open Publication No. Hei 11(1999)-343819, the following problems are mentioned as technical problems to be addressed for implementing an intermediate position locking mechanism in a hydraulic VTC: (1) a problem related to a driving force up to a locking position and (2) a problem related to the presence of a varying torque.
Further, in case of locking to the intermediate position, there can be a case where the phase shifting direction at the time of return of VTC for itself to the locking position is not limited to a delay direction but is an advance direction, depending on VTC phase in the last-time engine stop. A varying torque acts on a cam shaft by virtue of a reaction force provided from a valve spring, but a mean value thereof always takes a value in a delay direction due to a frictional resistance on a bearing or cam surface. It is possible to rely on this frictional resistance torque if the direction of return to the locking position is one delay direction, but this driving force is not sufficient as a driving force in an advance direction in addition to the delay direction. It is newly required to ensure a driving force for shifting phase in both directions.
The variation of torque acting on the cam shaft gives rise to the problem that in case of adopting a VTC phase locking means using a locking pin, if a locking pin—hole fitting gap is made too small, the fitting of the two becomes difficult, while if the gap is made too large, beating noise and damage are apt to occur due to looseness.
If the locking pin and the fitting hole are formed in a tapered shape, it seems possible to address the above problem that the fitting is difficult, but the pin axis and the hole axis cannot be made completely coincident with each other due to errors in parts dimensions and assembly (particularly it is impossible to make a radial deviation zero). Thus, the problem of beating noise remains to be addressed. Moreover, the tapered shape causes a component of a force to be created in a direction to release the locking pin, with a consequent fear of occurrence of a new problem that the reliability of the locking function is impaired.
As set forth above, in such a conventional technique as disclosed in Japanese Patent Laid-Open Publication No. 2001-241307, consideration is given to neither the subject that a driving force for phase shift in both delay and advance directions is to be ensured nor the subject that a rocking motion caused by a varying torque acting on a cam shaft due to a reaction force from a valve spring and looseness caused by a locking pin. Further, the structure disclosed in Japanese Patent Laid-Open Publication No. Hei 11(1999)-343819 cannot guarantee an automatic return to the intermediate locking position from both advance and delay directions.
Accordingly, in the present invention, with a view to enabling a phase control over a wide range by locking to an intermediate position at the time of starting of an engine, it is a first subject how a driving force for self-effort return in both delay and advance directions is to be ensured during a period in which an external VTC driving force cannot be expected such as during engine stop or during cranking. It is a second subject how a phase angle is to be locked positively without the occurrence of vibration and noise caused by for example looseness under the action of a varying torque acting on a cam shaft. It is a third subject how the locked state in the intermediate position is to be released at the time of performing an ordinary moving angle control.
For addressing the above-mentioned problems, the present invention mainly adopts the following constructions.
In one aspect of the present invention there is provided a phase controller having a first rotating member and a second rotating member adapted to be rotated through the first rotating member and controlling a phase angle as a relative rotational position between the first and second rotating members, the phase controller including: a first guide portion mounted unrotatably relative to the first rotating member and occupying a part on a circumference at a certain radial position; a second guide portion mounted unrotatably relative to the second rotating member and arranged alternately with the first guide portion in the direction of a circumference at the same radial position as the certain radial position; a first wedge member disposed between the first and second guide portions in one circumferential direction of the first guide portion on the circumference; a second wedge member disposed between the first and second guide portions in the other circumferential direction of the first guide portion; urging means for urging the first and second wedge members to move in one axial direction simultaneously; and drive means for moving the first and second wedge members in an opposite axial direction, wherein the first and second wedge members are moved in the one axial direction into close contact with both the first and second guide portions by the urging means.
In the above phase controller, the first and second guide portions each have a shape such that a circumferential gap between both guide portions becomes smaller in the one axial direction, and the first and second wedge members disposed within the circumferential gap also each have a shape such that the circumferential size decreases in the one axial direction.
In another aspect of the present invention there is provided a valve timing controller for an internal combustion engine, including: a first rotating member to which a rotating force is transmitted from a crank shaft; a second rotating member configured to transmit a rotating force to a cam shaft; a phase shifting mechanism mounted so as to straddle the first and second rotating members and shifting a relative rotation phase of the cam shaft with respect to the crank shaft in accordance with the state of the internal combustion engine; contact/decontact portions adapted to move relatively in directions in which respective surfaces come into contact with or separate from each other in accordance with the shifting of the phase performed by the phase shifting mechanism, the distance between the surfaces varying in the axial direction of the first and second rotating members; a restraint member disposed so as to be movable between the surfaces of the contact/decontact portions and adapted to restrain the phase of the phase shifting mechanism at a predetermined position in a contacted state with the surfaces of the contact/decontact portions upon movement in one axial direction of the first and second rotating members and become spaced from at least one of the surfaces of the contact/decontact portions to release the phase-restrained state of the phase shifting mechanism upon movement in the other axial direction; and a restraint control mechanism configured to cause the restraint member to move in accordance with the state of the internal combustion engine, wherein the restraint member is disposed so as to be positioned between the surfaces of the contact/decontact portions even in the phase-restraint released state of the phase shifting mechanism.
According to the present invention, for ensuring not only the effect of phase conversion to an advance side but also the effect of phase conversion to a delay side, the locking position at the time of engine starting is set to an intermediate position in a control range, whereby it is possible to attain both the improvement of fuel economy in idling and an increase of torque in high-speed operation.
A phase controller (a cam shaft phase controller for an internal combustion engine as an example) having an intermediate position locking function according to a first embodiment of the present invention will be described in detail below with reference to
In
In an intermediate position unlocked state shown in
The front plate 3 corresponds to a first guide member and a parallel guide portion 3a thereof is disposed in a portion a little smaller than half of the whole of a circumference E, as shown in
In this embodiment, an end in a delay direction of the slant guide portion 7a is of a shape having a certain inclination angle in
The contour of the wedge member (1) 16 and that of the wedge member (2) 17 are respectively provided with portions parallel to both ends of the parallel guide portion 3a and portions positioned at both ends of the slant guide portion 7a and having an inclination angle in
In the intermediate position unlocked state (the state shown in
The body 2 and the vane 6 introduce pressure-increased oil into the delay oil chambers 10 (see
In the intermediate position locked state shown in
In the state shown in
In
In other words, the intermediate locking position is set close to a most delayed position from the center of the entire control range. In this embodiment, a stopper 18 is installed into the groove 13a of the release piston 13 at the portion not fitted with the groove fitting portions 16a and 17a of the wedge members (1) 16 and (2) 17 respectively to inhibit movement of the wedge members 16, 17 in the direction of the stopper 18, thereby preventing separation of the wedge members from the parallel guide portion 3a. Particularly, as to the wedge member (2) 17, by maintaining a circumferential position thereof close to the parallel guide portion 3a, the wedge member (2) 17 can be spaced from the stepped portion 7b of the slant guide portion 7a. Therefore, when the wedge member (2) 17 is pushed-in in any of operations subsequent to
Even if a positive torque, i.e., torque acting in the delay direction, is exerted on the cam shaft 5 or the slant guide portion 7a, since the wedge member (1) 16 is small in wedge angle, a frictional resistance surpasses a component of the circumferential force and the wedge member (1) 16 is not pushed out in the axial direction (leftwards). Therefore, the slant guide portion 7a is not returned in the delay direction, either. On the other hand, if a negative torque, i.e., torque acting in the advance direction, is exerted on the slant guide portion 7a, the slant guide portion 7a performs a phase shift freely in the advance direction because the slant guide portion 7a has a gap between it and the wedge member (2) 17 in the advance direction. After all, the slant guide portion 7a performs a phase shift in the advance direction intermittently with the cycle of a varying torque.
Usually, a varying torque acting on the cam shaft varies over both positive and negative regions, but a mean value thereof is a positive value, i.e., torque acting in the delay direction. Therefore, under the action of only the varying torque on the cam shaft during engine stop or starting, the average torque in the delay direction permits the VTC to shift phase in the delay direction. When the present phase lies on the advance side with respect to the intermediate locking position, the phase shifting mechanism in the advance direction in
The operation principle diagrams of intermediate position locking from
In this embodiment, moreover, since the stepped portion 7b is formed in the slant guide portion 7a, the circumferential gap among the members concerned in
A cam shaft phase controller for an internal combustion engine having an intermediate position locking function according to a second embodiment of the present invention will be described in detail below with reference to
In this second embodiment, the shapes of body 19, front plate 20, vane 21, slant guide 22, release piston 23, release oil chamber 24, locking spring 25, wedge member (3) 26, wedge member (4) 27, stopper 28 and center bolt 33 are different from those described in the first embodiment. Further, an Oldham's coupling 29 (slightly movable radially and coupled for integral operation in a rotational direction), a parallel guide 30, a thrust guide screw 31 and a sleeve 32 are used as additional members.
In
In this second embodiment, the front plate 20 is not formed with a parallel guide portion, but the parallel guide 30 as a separate member is formed with parallel guide portions 30a (erected axially from the inner peripheral edge of the parallel guide 30). The parallel guide 30 is connected to the front plate 20 through the Oldham's coupling 29. The two key portions (1) 29a of the Oldham's coupling 29 are fitted in the two key ways 20a of the front plate 20 and the other two key portions (2) 29b are fitted in the two key ways 30b of the parallel guide 30. The parallel guide 30 can perform a translational motion in a plane orthogonal to the axis but cannot perform a relative rotation with respect to the front plate 20. The parallel guide 30 and the Oldham's coupling 29 are inhibited from movement to the front side (to this side in
The parallel guide portions 30a of the parallel guide 30 are alternately arranged circumferentially on the same radius as the radius on which the slant guide portions 22a of the slant guide 22 are arranged, the slant guide 22 being fixed to the cam shaft 5 and the vane 21 with the center bolt 33. In this embodiment, as is seen from
The slant guide portions 22a are formed with stepped portions 22b for the same purpose as that in the first embodiment. The parallel guide portions 30a are respectively provided with cut portions 30c nearly centrally in the circumferential direction and the piston support portions 22c of the slant guide 22 are disposed respectively in those spaces. The piston support portions 22c have a slant contour like that of the slant guide portions 22a, but this shape is merely based on a strength-related reason and is not a shape for close contact with the wedge members, unlike the slant guide portions 22a.
The function of the piston support portions 22c of the slant guide 22 is such that their outer periphery surfaces guide the inner periphery surface of the release piston 23 to stabilize the attitude of the release piston 23 lest the piston should tilt. The outer periphery surface of a sleeve 32 is fixed by press-fitting to the inner periphery surfaces of the parallel guide portions 30a, which sleeve 32 is for preventing the wedge members (3) 26 and (4) 27 from falling off to the inner periphery side.
As in the first embodiment, the release piston 23 moves axially between
A structural feature of this second embodiment is that, as described above, the parallel guide portions 30a and the slant guide portions 22a are provided each in two places and the wedge members (3) 26, (4) 27 installed therebetween are also provided each two. Consequently, when the VTC is put in the intermediate position locked state (the state of
In contrast therewith, the phase controller of the first embodiment is provided with only one parallel guide portion 3a and one slant guide portion 7a and the torque in the delay or advance direction is borne by a couple of forces constituted by a working force in either the wedge member (1) 16 or the wedge member (2) 17 and a working force present in a turning pair center between the parallel guide portion 3a and the slant guide portion 7a, i.e., near the central axis. The arm length in this couple of forces corresponds to the radium of the circumference E on the average and the magnitude of each of the working forces which constitute the couple of forces is a value obtained by dividing the varying torque on the cam shaft 5 by the radius of the circumference E (see
In the second embodiment, since the parallel guide 30 formed with the parallel guide portions 30a is mounted through the Oldham's coupling 29, it can perform a translational motion in a plane orthogonal to the axis with respect to the front plate 20. Therefore, in the case where the magnitudes of working forces at two places acting on the parallel guide portions 30a through the two opposed wedge members differ due to a change of torque on the cam shaft 5 at the time of intermediate position locking and the couple of forces is not a complete couple of forces, the forces acting on the parallel guide 30 cannot be cancelled each other and, with the remaining force acting in the translational direction, the parallel guide 30 performs a translational motion in a plane orthogonal to the axis.
This motion decreases the larger one of the two working forces and increases the smaller one, so that the parallel guide 30 becomes stable at a place where both working forces coincide with each other. That is, according to this structure, the working forces in two opposed wedge members are sure to become approximately equal to each other, so that it is possible to level the surface pressures of the wedge members, thereby prevent a partial occurrence of a large surface pressure and improve the reliability.
The features of the phase controllers embodying the present invention and described above will now be described again with use of a constructional example of application to a valve timing controller (VTC) for an internal combustion engine. First, there are provided a first rotating member 3 (integral with the sprocket 1 and the body 2) which is rotated in synchronism with the engine crank shaft and a second rotating member 6 (integral with the slant guide 7) adapted to be rotated through the first rotating member 3 and connected integrally with the cam shaft. A first guide member 3a is mounted unrotatably to the first rotating member 3 and is positioned so as to occupy a part on the circumference at a certain radial position. A second guide member 7a is mounted unrotatably to the second rotating member 6 and is positioned so as to be circumferentially alternate with the first guide portion 3a at the same radial position. A wedge member (1) 16 is disposed between the first guide portion 3a and the second guide portion 7a on the aforesaid circumference and in one circumferential direction of the first guide portion 3a, while a wedge member (2) 17 is disposed between the first guide portion 3a and the second guide portion 7a in the opposite circumferential direction of the first guide portion 3a.
Further provided are urging means 15 using a spring or the like for moving the wedge members (1) 16 and (2) 17 in one axial direction simultaneously and drive means 13 using a hydraulic piston or the like for moving the wedge members (1) 16 and (2) 17 in an opposite axial direction. In this case, the shapes of the constituent members are such that the wedge members (1) 16 and (2) 17 can each be axially moved by the urging means 15 into close contact with both first and second guide portions 3a, 7a. In this VTC to which the present invention is applied, a phase shifting mechanism (not shown) for changing the phase of the first and second rotating members 3, 6 relative to each other in a normal state of control after engine starting is also installed separately from the above construction.
Consequently, according to the above embodiments of the present invention, during engine stop or cranking in re-starting in which the phase shifting mechanism does not function and the wedge members 16 and 17 are trying to move in one axial direction under the action of the urging means 15, a driving force advancing toward the locking position lying intermediate in the phase shifting range can be produced from any position. In the above state, the wedge members (1) 16 and (2) 17 are not yet in close contact with the first and second guide portions 3a, 7a, and the first rotating member 3 (integral with the sprocket 1) and the second rotating member 6 (integral with the cam shaft 5) with the first and second guide portions 3a, 7a attached thereto respectively rotate relatively with respect to each other and can effect phase shifting.
At this time, a varying torque which varies over both positive and negative regions is exerted on the cam shaft 5 under a reaction force provided from the valve spring, so that the first and second rotating members 3, 6 tend to perform a pivotal motion about a central axis relatively with respect to each other. As a result, the first and second guide portions 3a, 7a assume a state in which they sandwich the wedge member (1) 16 or the wedge member (2) 17 in between them under the action of the varying torque provided from the cam shaft 5. However, with respect to both wedge members (1) 16 and (2) 17, the wedge angle (an angle formed by tangential lines in the contacted portion of both first and second guide portions 3a, 7a when the wedge members are developed into a two-dimensional plane from their arranged state on the radius) is set sufficiently small. Therefore, the force of the wedge member 16 (17) being pushed back in the axial direction opposite to the urging means 15 under the sandwiching force of the first and second guide portions 3a, 7a is cancelled by a frictional resistance. This is also true of the case where the direction of the varying torque reverses and the other wedge member is sandwiched in between the first and second guide portions.
On the other hand, the varying torque from the cam shaft 5 repeats the state in which the absolute value thereof is sure to approach zero in the course of varying over both positive and negative regions. When the wedge member (1) 16 and the wedge member (2) 17 are not yet in close contact with the first and second guide portions 3a, 7a, there surely occurs a state in which one of the wedge members is not sandwiched in between both guide portions the moment the wedge member to be sandwiched in between both guide portions changes. In this state, a contact force or a frictional force between each wedge member and each guide portion acts on neither the wedge member (1) 16 nor the wedge member (2) 17, so that the wedge members are sure to be moved in the direction of close contact with the guide portions by the urging means 15.
That is, the wedge members (1) 16 and (2) 17 are moved intermittently in one axial direction by the urging means 15 without being returned in the opposite direction and are sure to move up to the position where they come into close contact with both first and second guide portions 3a, 7a. If the wedge members (1) 16 and (2) 17 move axially and simultaneously, it is only when the first rotating member 3 and the second rotating member 6 are in a predetermined phase relation that they can come into close contact with both first and second guide portions 3a, 7a. By setting the phase to the intermediate position locking phase the VTC can return to the locking position for itself by utilizing the varying torque on the cam shaft 5 in the delay direction or in the advance direction. Once the VTC occupies this position, the wedge members 16 and 17 are never pushed back in the opposite axial direction, so that there is maintained a locked state as a closely contacted, looseness-free state in which the wedge members are in close contact with both first and second guide portions 3a, 7a.
When sufficient hydraulic oil is fed from the oil supply pump after starting of the engine, the drive means using a hydraulic piston for example operates to move the wedge members (1) 16 and (2) 17 in the opposite axial direction, thereby releasing the locked state in which the wedge members 16, 17 and the first and second guide portions 3a, 7a are in close contact/non-contact with each other. This released state is a state in which the members inhibiting the relative rotation between the first rotating member 3 and the second rotating member 6 have been removed. Therefore, the phase shifting control in normal condition can be performed using the conventional phase shifting mechanism installed separately from the construction of the present invention.
Number | Date | Country | Kind |
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2006-017733 | Jan 2006 | JP | national |
Number | Name | Date | Kind |
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6276322 | Sekiya et al. | Aug 2001 | B1 |
Number | Date | Country |
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11-343819 | Dec 1999 | JP |
2001-241307 | Sep 2001 | JP |
Number | Date | Country | |
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20070169732 A1 | Jul 2007 | US |