Patent Grant
9004028
The present invention relates to a valve timing control apparatus for adjusting opening/closing timings of an intake valve and an exhaust valve of an internal combustion engine of an automobile or the like according to a driving condition.
A valve timing control apparatus is used in an internal combustion engine such as an engine for an automobile. The apparatus adjusts valve opening/closing timings for rendering the internal combustion engine into a favorable operational condition, by varying the relative rotational phase between a driving-side rotary member rotated in synchronism with a crankshaft and a driven-side rotary member disposed coaxial with the driving-side rotary member and rotated in synchronism with a camshaft.
A valve timing control apparatus disclosed in PTL 1 is provided with a spring member configured to urge the relative rotational phase to the angle advancing direction. More particularly, this spring member provides the urging to the angle advancing direction in order to offset a force acting to the angle retarding direction that occurs in association with a torque variation of a cam mounted on the camshaft.
On the other hand, with the valve timing control apparatuses disclosed in PTL 1 and PTL 2, aluminum is employed as the material for forming the driving-side rotary member and the driven-side rotary member instead of the conventionally employed cast-iron type material or the like. In general, as aluminum is light-weight compared with the cast-iron type material, aluminum is suitable for use in an automobile for which weight reduction is sought for.
At the time of varying the relative rotational phase, there occurs a change in the dimension of the spring member in the radial direction. In association with this change in the radial dimension of the spring member, there occurs a sliding displacement between the radially extending face of the spring member and at least one of the driving-side rotary member and the driven-side rotary member. However, in case a soft material such as aluminum is employed as the material forming the driving-side rotary member and the driven-side rotary member as is the case with PTL 1 and PTL 2, there occurs the problem of wear in at least one of the driving-side rotary member and the driven-side rotary member in association with such change in the radial dimension of the spring member.
The present invention has been made in view of the above-described state of the art. The object of the invention is to provide a valve timing control apparatus with which it is possible to restrict such wear of the driving-side rotary member and the driven-side rotary member even when a sliding displacement occurs between the radially extending face of the spring member and at least one of the driving-side rotary member and the driven-side rotary member.
According to a first characterizing feature provided by the present invention for achieving the above-noted technical object, a valve timing control apparatus comprises:
a driving-side rotary member rotated in synchronism with a crankshaft of an internal combustion engine;
a driven-side rotary member disposed coaxial with the driving-side rotary member and rotated in synchronism with a valve opening/closing camshaft of the internal combustion engine; and
a retard angle chamber and an advance angle chamber formed by the driving-side rotary member and the driven-side rotary member, the retard angle chamber being configured to move a relative rotational phase of the driven-side rotary member relative to the driving-side rotary member to an angle retarding direction, the advance angle chamber being configured to move the relative rotational phase to an angle advancing direction, respectively, in response to feeding of a work oil respectively thereto;
wherein the driving-side rotary member includes a housing main body portion disposed on the radial outer side of the driven-side rotary member and at least two housing side face portions, each housing side face portion being provided at an end of the housing main body portion corresponding thereto along the axial direction of the camshaft and slidable relative to the driven-side rotary member; and
a spring member disposed between the driven-side rotary member and the housing side face portion along the axial direction of the camshaft, the spring member urging the relative rotational phase to the angle advancing direction or the angle retarding direction; and
a spring washer disposed between the driven-side rotary member and the spring member;
wherein the spring washer includes a hook portion which extends along the axial direction of the camshaft; and
one end of the spring member is engaged with the driven-side rotary member via the hook portion.
With the above-described arrangement, since a spring washer is disposed between the driven-side rotary member and the spring member along the axial direction of the camshaft, occurrence of wear of the driven-side rotary member in association with change in the radial dimension of the spring member can be effectively restricted. Further, since a hook portion is formed in the spring washer, rotational displacement of the spring washer can be restricted advantageously. Moreover, since one end of the spring member is engaged with the driven-side rotary member via the hook portion, no direct contact occurs between the spring member and the driven-side rotary member. Therefore, wear of the driven-side rotary member by the spring member can be restricted advantageously.
According to a second characterizing feature provided by the present invention, the spring washer includes a washer portion for a fastening member for fastening the camshaft with the driven-side rotary member.
With the above-described arrangement, the spring washer includes a washer portion for a fastening member. Hence, as compared with the case of using two washers, the axial length of the camshaft of the valve timing control apparatus can be reduced advantageously. Further, since the single member, i.e. the spring washer, acts not only as a washer for the spring member, but as a washer for the fastening member, increase in the number of components can be restricted advantageously.
According to a third characterizing feature provided by the present invention, the spring washer includes a guide portion for maintaining the posture of the spring member.
With the above-described arrangement, since the posture of the spring member can be maintained by the guide portion, it is possible to allow the urging force of the spring member to act on the driven-side rotary member in a stable manner.
According to a fourth characterizing feature provided by the present invention, the driven-side rotary member is formed of aluminum and the spring washer is formed of a material having a higher strength than aluminum.
With the above-described arrangement, even if soft aluminum is employed as the material for forming the driven-side rotary member, wear of the driven-side rotary member in association with change in the radial dimension of the spring member can be restricted by the spring washer formed of a material having higher strength than aluminum.
According to a fifth characterizing feature provided by the present invention, the spring member is set under a compressed state compressed from its free length to a predetermined length, so as to press the housing side face portion on the side opposite the side where the camshaft is provided.
With the above-described arrangement, as the spring member is set under a compressed state compressed from its free length to a predetermined length, the driven-side rotary member and the housing side face portion on the side opposite the side where the camshaft is provided are pressed to sides away from each other along the axial direction of the camshaft.
Normally, the driving-side rotary member is pivotally supported and has its axis fixedly determined by the camshaft or the driven-side rotary member rotatable in synchronism with the camshaft. In this way, as the urging force of the spring member is directed to the axial direction of the camshaft to act on the housing side face portion on the side opposite the camshaft, the housing side face portion on the side opposite the camshaft can be pivotally supported by the pressing force provided by the spring member, even if being not pivotally supported by the camshaft or the driven-side rotary member.
A valve timing control apparatus relating to the present invention will be described with reference to the accompanying drawings by way of an embodiment shown therein wherein the apparatus is applied as an intake valve side or an exhaust valve side valve timing control apparatus of an automobile.
The driving-side rotary member 10 is comprised of the housing main body portion 10a disposed on the radial outer side of the driven-side rotary member 11, the housing side face portion 10b disposed on the side opposite the camshaft 101 across the housing main body portion 10a and the housing side face portion 10c disposed on the side closer to the camshaft 101 than the housing main body portion 10a. The housing side face portion 10c is pivotally supported by the camshaft 101 via a bearing member 15. Further, the housing main body portion 10a is pivotally supported by the driven-side rotary member 11. Also, the housing side face portion 10b is configured so as not to be displaced from the axis of the driven-side rotary member 11 by the pressing force provided from the torsion spring 12 described later and acting to the axial direction of the cam shaft 101. On the other hand, the housing main body portion 10a and the housing side face portions 10b, 10c are fastened together with four bolts 16, thus together constituting the driving-side rotary member 10. Hence, the housing side face portion 10b is set under a compressed state by the pressing force of the torsion spring 12 and the fastening forces of the bolts 16. Accordingly, in the valve timing control apparatus according to the present embodiment, as the driven-side rotary member 11 does not provide direct pivotal support for the housing side face portion 10b, the axial length of the camshaft 101 can be reduced. Advantageously, the driving-side rotary member 10 can be formed of a metal such as aluminum which is light-weight and can be easily worked.
Along the outer circumference of the housing side face portion 10c, a timing sprocket 10d is formed. Between this timing sprocket 10d and the crankshaft 100, there is mounted a force transmission member 102 such as a timing chain, a timing belt, etc. In operation, when the internal combustion engine E is driven, the crankshaft 100 is rotated to rotate the timing sprocket 10d via the force transmission member 102. And, in association with this rotation of the timing sprocket 10d, the valve timing control apparatus 1 revolves in a rotational direction S.
The driven-side rotary member 11 is mounted on the radially inner side of the housing main body portion 10a. Based on the function of work oil in the retard angle chamber 20 and the advance angle chamber 21, the relative rotational phase of the driven-side rotary member 11 relative to the driving-side rotary member 10 is varied and the driven-side rotary member 11 is rotated in synchronism with the driving-side rotary member 10. Further, the driven-side rotary member 11 is fastened to the camshaft 101 by a cam bolt 102, so that the driven-side rotary member 11 and the camshaft 101 are rotated in synchronism. Advantageously, the driven-side rotary member 11 can be formed of a metal such as aluminum which is light-weight and can be easily worked.
Incidentally, the work oil to the retard angle chamber 20 and the advance angle chamber 21 is discharged from an unillustrated oil pump and fed thereto after its supply amount control by an unillustrated oil control valve. This oil control valve controls also discharging of the work oil from the retard angle chamber 20 and the advance angle chamber 21 to an unillustrated oil pan.
As shown in
In the accommodating portion 11a, the torsion spring 12 is mounted. This torsion spring 12 comprises a length of elongate metal wire coiled in the spiral form, with one end 12a and the other end 12b of the wire being bent to be aligned with the axial direction of the camshaft 101. With this torsion spring 12, the one end 12a thereof engages with the driven-side rotary member 11 via the hook portion 14b of the spring washer 14 to be described later and the other end 12b thereof engages with the housing side face portion 10b. And, the torsion spring 12 urges the relative rotational phase of the driven-side rotary member 11 relative to the driving-side rotary member 10 to the angle advancing direction S2. Further, this torsion spring 12 is set under a compressed state compressed from its free length to a predetermined reduced length, thereby to press the housing side face portion 11b opposite the camshaft 101 away from this camshaft 101.
In the accommodating portion 11a, in other words, between the driven-side rotary member 11 and the torsion spring 12 along the axial direction of the camshaft 101, the spring washer 14 is provided.
As described above, with the valve timing control apparatus 1 according to the instant embodiment, even when a soft material such as aluminum is employed as the material for forming the driven-side rotary member 11, since the spring washer 14 is interposed between the driven-side rotary member 11 and the torsion spring 12, wear of the driven-side rotary member 11 in association with change in the radial dimension of the torsion spring 12 can be restricted by the spring washer portion 14c advantageously.
Incidentally, in the foregoing embodiment, as the spring washer 14, there was disclosed an example thereof in which it includes the hook portion 14b that extends along the axial direction of the camshaft 101 in order to prevent the one end 12a of the torsion spring 12 from coming into direct contact with the driven-side rotary member 11. However, the invention is not limited thereto. For instance, the spring washer 14 can include a hook portion that extends along the axial direction of the camshaft 101 in order to prevent the other end 12b of the torsion spring 12 from coming into direct contact with the housing side face portion 10b. In this case, advantageously, the guide portion 14a of the spring washer 14 can be formed to extend further toward the housing side face portion 10b along the axial direction of the camshaft 101.
Further, in the foregoing embodiment, the torsion spring 12 was configured to urge the relative rotational phase to the angle advancing direction S2. Instead, the torsion spring can be configured to urge the relative rotational phase to the angle retarding direction S1. In the case of using such torsion spring configured to urge the phase to the angle retarding direction S1, with a valve timing control apparatus having a lock mechanism for locking the relative rotational phase to the most retarded angle phase, the lock mechanism can provide even more reliable locking function.
The present invention can be applied to a valve timing control apparatus wherein even when sliding occurs between a surface that extends along the radial direction of a spring member and at least one of a driving-side rotary member and a driven-side rotary member, wear of the at least one of the driving-side rotary member and the driven-side rotary member can be prevented.
| Number | Date | Country | Kind |
|---|---|---|---|
| 2010-240586 | Oct 2010 | JP | national |
| Filing Document | Filing Date | Country | Kind | 371c Date |
|---|---|---|---|---|
| PCT/JP2011/073313 | 10/11/2011 | WO | 00 | 3/7/2013 |
| Publishing Document | Publishing Date | Country | Kind |
|---|---|---|---|
| WO2012/056874 | 5/3/2012 | WO | A |
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| Number | Date | Country | |
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