JPWO2020162016A1 - Internal combustion engine valve timing controller - Google Patents

Abstract

A speed reducer 13 that rotates the driven member 9 relative to the sprocket 1 by rotating the eccentric shaft 21, an electric motor 12 having a motor shaft 17 that rotates the eccentric shaft via an old dam joint 20, and a driven member cam. It includes a cam bolt 14 to be coupled to the shaft 2. The cam bolt is formed to penetrate in the internal axial direction and has an oil passage hole 35 communicating with an oil supply passage 34 for supplying lubricating oil to the inside of the internal combustion engine. This oil passage hole has a small-diameter first oil hole 38 and a second oil hole 39 on the downstream side of the large-diameter main passage hole 37a, and an oldam joint and a speed reducer are provided by lubricating oil injected from both oil holes. It is designed to directly lubricate at least one of the above.

Description

The present invention relates to, for example, a valve timing control device for an internal combustion engine that controls the opening / closing timing of an intake valve or an exhaust valve.

As a valve timing control device for a conventional internal combustion engine, the one described in Patent Document 1 below is known.

In this valve timing control device, a planetary gear device is used as a speed reducer. As a method of lubricating the planetary gear device, the lubricating oil discharged from the mechanical pump into the introduction passage formed inside the camshaft is introduced into the lubrication chamber through the introduction port. As a result, in the lubricating chamber, the lubricating oil is sequentially supplied to the friction generating portion of the planetary gear device.

Japanese Unexamined Patent Publication No. 2017-008837 (Fig. 4)

However, in the conventional valve timing control device, as described above, the introduction passage is formed inward from one end of the camshaft along the direction of the rotation axis deviating from the rotation axis center. For this reason, the processing work becomes complicated, and there is a possibility that the processing cost and the like will rise.

The present invention has been devised in view of the above-mentioned conventional technical problems, and is an internal combustion engine capable of facilitating and reducing the cost of machining an oil passage hole for supplying lubricating oil to a speed reducer. One purpose is to provide a valve timing control device.

One of the preferred embodiments is, in particular, a speed reducer provided between the drive rotating body and the driven rotating body, which rotates the driven rotating body relative to the driving rotating body by rotating the input shaft. An electric motor having a motor shaft that rotates the input shaft via a joint,
A cambolt that connects the driven rotating body to the camshaft, and has an oil passage hole inside that communicates with a supply passage that supplies lubricating oil to the inside of the internal combustion engine and that can supply lubricating oil to the joint and the speed reducer. It is characterized in that it is provided with the cam bolt having.

According to a preferred embodiment of the present invention, the work of processing the oil passage hole for supplying the lubricating oil to the speed reducer becomes easy, and the increase in cost can be suppressed.

It is a partial vertical sectional view of the valve timing control device in the 1st Embodiment of this invention. It is an exploded perspective view which shows the main component provided to this embodiment. It is an enlarged view of the main part of this embodiment shown in FIG. FIG. 3 is a cross-sectional view taken along the line AA of FIG. It is a B arrow view of FIG. It is a front view of the electric motor provided in this embodiment. It is a cross-sectional view taken along the line CC of FIG. An eccentric axis provided in the present embodiment is shown, where A is a side view of the eccentric axis, B is a front view of the eccentric axis, and C is a sectional view taken along line DD of B. It is a partial vertical sectional view of the valve timing control device in the 2nd Embodiment of this invention. It is a partial vertical sectional view of the valve timing control device in the 3rd Embodiment of this invention. It is a partial vertical sectional view of the valve timing control device in 4th Embodiment of this invention. It is a perspective view which shows the front cover provided in 4th Embodiment.

Hereinafter, embodiments of the valve timing control device for an internal combustion engine according to the present invention will be described in detail with reference to the drawings. In this embodiment, the valve timing control device is applied to the intake side, but it can also be applied to the exhaust side.
[First Embodiment]
FIG. 1 is a partial vertical sectional view showing a valve timing control device in the present embodiment, FIG. 2 is an exploded perspective view showing the main components used in the present embodiment, and FIG. 3 is the present embodiment shown in FIG. An enlarged view of a main part, FIG. 4 is a sectional view taken along line AA of FIG.

As shown in FIGS. 1 and 2, the valve timing control device is rotatably supported on a cylinder head 01 via a timing sprocket 1 (hereinafter referred to as a sprocket 1) which is a drive rotating body and a bearing 02. It is provided with a camshaft 2 and a phase changing mechanism 3 arranged between the sprocket 1 and the camshaft 2 and changing the relative rotation phases of the two 1 and 2 according to the engine operating state.

The sprocket 1 is integrally formed in an annular shape by an iron-based metal which is a metal material as a whole. It includes a gear portion 1b that receives a rotational force from a crankshaft of an internal combustion engine via an outer timing chain.

A chain case (not shown) coupled to the cylinder block of the internal combustion engine and the cylinder head 01 is provided on the outer periphery of the sprocket 1.

An annular internal gear 5 constituting a part of the speed reducer 13, which will be described later, is integrally provided on the front end side of the sprocket body 1a. The internal gear 5 is integrally coupled to the sprocket body 1a from the direction of the rotation axis, and a plurality of wave-shaped internal teeth 5a are formed on the inner circumference.

The sprocket body 1a is provided with a slide bearing mechanism 6 between the inner peripheral surface thereof and the outer peripheral surface of a driven member 9 described later, which is a driven rotating body fixed to one end 2a in the rotation axis direction of the camshaft 2. There is. The slide bearing mechanism 6 bearings the sprocket 1 on the outer periphery of the driven member 9 (camshaft 2) so as to be relatively rotatable.

Further, a holding plate 8 is fixed to the rear end surface of the sprocket body 1a on the side opposite to the internal gear 5 in the axial direction. As shown in FIGS. 1, 2 and 4, the holding plate 8 is formed in an annular shape by a plate material of an iron-based metal which is a metal material, and the outer diameter is set to be substantially the same as the outer diameter of the sprocket body 1a. ing. Further, in the holding plate 8, a central hole 8a is formed through the center so that the inner peripheral portion 8b on the central hole 8a side covers one end opening on the camshaft 2 side of the bearing recess 10 described later in the slide bearing mechanism 6. Is located in. In the inner peripheral portion 8b, the portion serving as the hole edge of the central hole 8a is located inside the tooth bottom surface of the internal tooth 5a of the internal gear 5.

Further, the holding plate 8 is integrally provided with a stopper convex portion 8c protruding in the radial direction, that is, in the central axis direction, at a predetermined position on the inner peripheral edge of the central hole 8a. The stopper convex portion 8c is formed in a substantially inverted trapezoidal shape, and the tip surface is formed in an arc shape along the arcuate inner peripheral surface of the stopper concave groove 9f of the fixed end portion 9b described later of the driven member 9. ..

FIG. 5 is a view taken along the line B of FIG.

Further, a front cover 15 which is a cover member is provided on the front end surface of the sprocket 1 on the internal gear 5 side. As shown in FIGS. 1, 2, and 5, the front cover 15 is formed by punching, for example, an iron-based metal plate in an annular shape by press molding, and an eccentric shaft 21 described later is inserted and arranged in the center. The insertion hole 15a is formed through.

Six bolt insertion holes 1c and 15b through which a plurality of (six in this embodiment) bolts 7 are inserted are located at substantially equal intervals in the circumferential direction on the outer peripheral portions of the sprocket body 1a including the internal gear 5 and the front cover 15. It is formed through each of them. Further, the holding plate 8 is formed with six female screw holes 8d to which the male screw portion 7a at the tip of each bolt 7 is screwed at a position corresponding to the bolt insertion holes 1c and 15b.

As shown in FIG. 2, two positioning pins 28a and 28b are inserted into each side of the two bolt insertion holes 1c of the sprocket body 1a and the corresponding two female screw holes 8d of the holding plate 8. Small holes 1d and 8e for positioning are provided, respectively. As a result, the holding plate 8 is positioned in the circumferential direction and the axial direction with respect to the sprocket 1.

The camshaft 2 has two drive cams per cylinder that open and operate an intake valve (not shown) on the outer periphery. Further, the camshaft 2 is integrally provided with a flange portion 2b for axially positioning via a bearing 02 at one end portion 2a on the phase changing mechanism 3 side in the rotation axis direction.

Further, the camshaft 2 has an insertion hole 2c formed along the direction of the internal axial center from the tip surface of the one end portion 2a. In the insertion hole 2c, the shaft portion 14b of the cam bolt 14, which will be described later, is inserted, and the female screw portion 2d to which the male screw portion 14c of the cam bolt 14 is fastened is formed on a part of the inner peripheral surface on the one end portion 2a side. .. Further, in the insertion hole 2c, an oil supply passage 34 forming a part of a lubricating oil supply passage to be described later is continuously formed inside the female screw portion 2d.

Further, a positioning pin 2g for positioning in the rotation direction with the driven member 9 is press-fitted and fixed to the tip of one end 2a of the camshaft 2 from the rotation axis direction.

The driven member 9 is integrally formed of an iron-based metal, and as shown in FIGS. 1 to 4, the driven member 9 is integrally provided with the disk-shaped main body 9a and the rear end side (camshaft 2 side) of the disk-shaped main body 9a. It is mainly composed of an annular fixed end portion 9b.

The disk-shaped main body 9a is integrally provided with a journal portion 11 constituting a part of the slide bearing mechanism 6 on the outer peripheral surface. Further, the disk-shaped main body 9a is formed through a bolt insertion hole 9c into which an intermediate shaft portion 14g of a cam bolt 14, which will be described later, is inserted and fitted in the direction of the internal axial center including the fixed end portion 9b. The inner diameter of the bolt insertion hole 9c is formed to be larger than the inner diameter of the insertion hole 2c of the camshaft 2.

The fixed end portion 9b has a certain wall thickness and protrudes from the disk-shaped main body 9a in the two directions of the camshaft. Further, the fixed end portion 9b has an annular fitting groove 9d in which the tip end portion of the one end portion 2a of the camshaft 2 is fitted substantially in the center of the outer surface on the camshaft 2 side (the outer peripheral side of the bolt insertion hole 9c). It is formed. A positioning hole 9e into which the positioning pin 2g of the camshaft 2 described above is inserted from the axial direction is formed on the bottom surface of the fitting groove 9d.

Further, the fixed end portion 9b is formed with a stopper concave groove 9f in which the stopper convex portion 8c of the holding plate 8 enters the outer peripheral surface along the circumferential direction. The stopper concave groove 9f is formed in an arc shape having a predetermined length in the circumferential direction. The stopper convex portion 8c is configured such that both side surfaces rotated in the arcuate length range of the stopper concave groove 9f come into contact with the facing surfaces of the stopper concave groove 9f in the circumferential direction. As a result, the relative rotation position of the camshaft 2 on the maximum advance angle side or the maximum retard angle side with respect to the timing sprocket 1 is mechanically regulated.

Further, the driven member 9 is fastened and fixed to the camshaft 2 from the axial direction by the cam bolt 14 in a state where the tip end portion of the one end portion 2a of the camshaft 2 is fitted in the fitting groove 9d from the axial direction. There is.

As shown in FIGS. 1 and 2, the slide bearing mechanism 6 is provided on the annular bearing recess 10 formed on the inner peripheral surface of the sprocket body 1a and the outer peripheral surface of the disk-shaped body 9a, and is provided on the outer peripheral surface of the disk-shaped body 9a. It has a journal portion 11 arranged inside and a holding plate 8 that covers one end opening of the bearing recess 10.

The bearing recess 10 is formed only on the inner peripheral surface side of the sprocket body 1a closer to the camshaft 2 side without extending from one side surface of the sprocket body 1a on the holding plate 8 side to the inner gear 5. Further, as shown in FIG. 1, the bearing recess 10 has a substantially rectangular cross-sectional shape along the radial direction from the rotation axis of the sprocket 1, and a part of the bearing recess 10 is formed at a position where each gear portion 1b is formed. It is arranged so as to overlap in the axial direction.

Further, the bearing recess 10 has a sliding bearing surface 10a formed on the bottom surface of the annular shape. Further, the bearing recess 10 has an inner side surface 10b on the other end side opposite to the holding plate 8 in the axial direction, which is cut out at a substantially right angle in the radial direction from the slide bearing surface 10a. Further, as described above, the bearing recess 10 is opened to the outside at the other end on the camshaft 2 side, and the opened other end is opened by the inner side surface 8f of the inner peripheral portion 8b of the holding plate 8. It is covered.

The journal portion 11 projects radially outward from the outer peripheral surface of the disk-shaped main body 9a, and is formed in a rectangular shape having a cross-sectional shape substantially similar to the cross-sectional shape of the bearing recess 10. Further, since the bearing recess 10 overlaps with each gear portion 1b in the axial direction, a part of the journal portion 11 is also arranged to overlap with each gear portion 1b of the sprocket 1 in the axial direction.

Further, the journal portion 11 is formed with annular grooves on both sides in the axial direction of the base portion 11a, which is a binding site with the disk-shaped main body 9a. Further, in the journal portion 11, the annular outer peripheral surface is slidable on the entire sliding bearing surface 10a of the bearing recess 10. Each annular groove is designed to prevent the journal portion from coming into contact with the inner side surface 8f of the holding plate 8 and the inner side surface 10b of the bearing recess 10 when the driven member 9 is rotated.

Further, in the journal portion 11, one end surface on the front cover 15 side in the axial direction is slidable on the inner side surface 10b of the bearing recess 10. The inner surface surface 10b abuts on one end surface of the journal portion 11 when the sprocket 1 is tilted to regulate the movement of one thrust.

Further, in the journal portion 11, the other end surface on the holding plate 8 side in the axial direction is slidable on the inner side surface 8f of the inner peripheral portion 8b of the holding plate 8. The inner side surface 8f of the holding plate 8 abuts on the other end surface of the journal portion 11 when the sprocket 1 is tilted to regulate the thrust movement of the other.

As shown in FIGS. 1 to 3, the cam bolt 14 is formed on a substantially columnar head portion 14a, a shaft portion 14b integrally fixed to the head portion 14a, and an outer peripheral surface of the shaft portion 14b. It has a male screw portion 14c screwed to the female screw portion 2d of the camshaft 2.

The head 14a is formed with a hexagonal tool hole 14d at the tip of which a tool such as a hexagon wrench is inserted. Further, the head 14a is subjected to heat treatment such as high frequency quenching on the entire outer peripheral surface 14e, and the hardness of the head 14a is higher than that of other parts of the head 14a. The other portion is, for example, a seat surface 14f which is an axial side surface of the head portion 14a to which the intermediate shaft portion 14g described later of the shaft portion 14b is connected. Further, each needle roller 25a of the needle bearing 25 is rotatably supported on the high hardness outer peripheral surface 14e of the head portion 14a. When the male screw portion 14c of the cam bolt 14 is screwed into the female screw portion 2d of the camshaft 2 and fastened, the seat surface 14f is on the facing surface outside the hole edge of the bolt insertion hole 9c of the disk-shaped main body 9a of the driven member 9. It is designed to be seated.

The shaft portion 14b is integrally provided with a large-diameter intermediate shaft portion 14g at the base portion with the head portion 14a, that is, at the center of the seat surface 14f in the axial direction of the head portion 14a. The outer diameter of the intermediate shaft portion 14g is formed to be larger than the outer diameter of the male screw portion 14c of the shaft portion 14b, and is slightly smaller than the inner diameter of the bolt insertion hole 9c of the driven member 9. As a result, the intermediate shaft portion 14g is inserted and fitted into the inner peripheral surface of the bolt insertion hole 9c with a minute clearance to ensure the coaxiality between the driven member 9 and the camshaft 2.

That is, the intermediate shaft portion 14g secures the coaxiality between the driven member 9 and the camshaft 2 by inserting and fitting the driven member 9 into the bolt insertion hole 9c when the driven member 9 is connected to the camshaft 2 by the cam bolt 14. It has become. Therefore, the insertion fitting of the intermediate shaft portion 14g into the bolt insertion hole 9c is a state close to the so-called intermediate fitting, which is a mechanical fitting to ensure the coaxiality between the driven member 9 and the camshaft 2. To say.

Further, the length of the intermediate shaft portion 14g in the axial direction is set to be substantially the same as the length in the axial direction of the bolt insertion hole 9c, and the tapered portion 14h is provided at the joint portion of the shaft portion 14b with the male screw portion 14c. It is provided. The outer peripheral surface of the tapered portion 14h is formed so as to be inclined downward at a predetermined angle from the outer peripheral surface of the intermediate shaft portion 14g to the male screw portion 14c.

Further, an arcuate groove 14i is formed between the seat surface 14f of the head portion 14a and the intermediate shaft portion 14g (base portion). As shown in FIG. 3, the arcuate groove 14i is formed in an annular shape along the outer circumference of the intermediate shaft portion 14g. In the cam bolt 14, when the cam bolt 14 is tightened to the cam shaft 2 by the arcuate groove 14i, the seat surface 14f of the head 14a and the base portion of the intermediate shaft portion 14g become the hole edge of the bolt insertion hole 9c of the driven member 9. Is in a non-contact state without contact.

As shown in FIGS. 1 and 2, the phase changing mechanism 3 is transmitted from the electric motor 12 arranged on the front end side of the fixed end portion 9b of the driven member 9 and the electric motor 12 via the oldam joint 20. It is mainly composed of a speed reducer 13 that reduces the rotation speed and transmits the speed to the camshaft 2.

FIG. 6 is a front view of the electric motor 12, and FIG. 7 is a sectional view taken along line CC of FIG.

The electric motor 12 is a so-called brushless DC type motor, and as shown in FIGS. 1, 2 and 6, the bottomed cylindrical motor housing 16 fixed to the chain case and the rear of the motor housing 16. A motor stator (not shown) provided at the end and accommodating a stator coil and the like inside, a motor shaft 17 arranged on the inner peripheral side of the stator coil, and a cylindrical shape fixed to the outer periphery of the motor shaft 17. It has a permanent magnet of the motor housing 16 and a feeding mechanism 18 provided at a front end portion of the motor housing 16 opposite to the sprocket 1.

The motor housing 16 is formed in a substantially cup shape, and a through hole (not shown) through which the motor shaft 17 is inserted is formed substantially in the center of the front end portion (bottom wall). On the other hand, a flange portion 16a projecting outward in the radial direction is integrally provided on the outer periphery of the rear end portion. The flange portion 16a is integrally provided with three bracket pieces 16b at a position of about 120 ° in the circumferential direction. Further, bolt insertion holes 16c through which bolts for connecting to a chain case (not shown) are inserted are formed through the three bracket pieces 16b.

Further, three different bolt insertion holes through which the three bolts 29 are inserted are formed between the bracket pieces 16b in the circumferential direction of the flange portion 16a. Each bolt 29 is adapted to connect the feeding mechanism 18 to the motor housing 16.

The number of bolt insertion holes 16c, bolts 29, and the like can be further increased.

The motor stator is integrally formed mainly by the resin portion of the synthetic resin material, and the stator coil is molded and fixed inside.

The power feeding mechanism 18 has a housing 18a formed in a box shape by a synthetic resin material. Inside the housing 18a, an energization circuit such as a bus bar that supplies power to the electric motor 12 and a rotation sensor that detects the rotation position of the motor shaft 17 are housed and arranged. Further, the power feeding mechanism 18 is integrally provided with a power feeding connector 18b electrically connected to the energizing circuit and a signal connector (not shown) in the housing 18a.

The power supply connector 18b has an internal terminal connected to a battery, which is a power source, via a female terminal to a control unit (not shown). On the other hand, in the signal connector, a built-in terminal is connected to the control unit via a female terminal, and the rotation angle signal detected by the rotation sensor is output to the control unit.

The motor shaft 17 is formed in a columnar shape made of a metal material, and has two-sided width portions 17b and 17c formed along the tangential direction on the outer surface of the tip portion 17a on the speed reducer 13 side. Further, as shown in FIG. 6, a pair of fitting grooves 17d, 17e cut out from a direction orthogonal to the width across flats 17b, 17c are formed on the tip edge side of the tip portion 17a. A stopper member 19 for restricting the movement of the intermediate member 30 to the cam bolt 14 side, which will be described later, is fitted and fixed in both fitting grooves 17d and 17e from the radial direction.

Further, as shown in FIG. 3, the motor shaft 17 is arranged so that the tip portion 17a is close to the head portion 14a of the cam bolt 14 with a slight gap C from the direction of the rotation axis. Further, the entire tip portion 17a including the stopper member 19 can be inserted into the tool hole 14d from the axial direction.

The stopper member 19 is formed in a C-ring shape and can be elastically deformed in the diameter-expanding direction and the diameter-reducing direction by its own elastic force.

Further, an intermediate member 30 is provided at the tip portion 17a of the motor shaft 17. The intermediate member 30 constitutes a part of the Oldham joint 20, which is a joint connected to the speed reducer 13, and has a cylindrical shape fixed to the tip portion 17a of the motor shaft 17 as shown in FIG. It has a base 31. The tubular base portion 31 has a pair of flat surface portions 31a and 31b having a width across flats on both sides of a circular outer surface, that is, at 180 ° positions in the circumferential direction, whereby the outer shape is substantially oval. Is formed in.

Further, a through hole 32 into which the tip portion 17a of the motor shaft 17 is inserted is formed at the central position of the tubular base portion 31.

The through hole 32 is formed with a pair of facing surfaces 32a and 32b having a width across flats along the radial direction from the rotation axis of the motor shaft 17 on the inner peripheral surface of the circular shape. As a result, it is formed into an elliptical shape that is similar to the outer shape of the tubular base 31 in the radial direction. Therefore, the intermediate member 30 is movable in the radial direction (vertical direction in FIG. 6) with respect to the tip portion 17a of the motor shaft 17 via the oval through hole 32.

The tubular base portion 31 is provided with two transmission keys 33a and 33b, which are a pair of protruding portions, at substantially the center of the pair of flat surface portions 31a and 31b in the longitudinal direction (vertical direction in FIG. 6). Each of the transmission keys 33a and 33b is formed in a substantially rectangular plate shape, and projects radially outward from the two flat surface portions 31a and 31b of the tubular base portion 31.

As shown in FIG. 1, the speed reducer 13 is provided separately from the electric motor 12 in the axial direction, and each component is housed and arranged inside the sprocket 1 between the holding plate 8 and the front cover 15. ing.

Specifically, as shown in FIGS. 1 to 3 and 7, the speed reducer 13 includes a cylindrical eccentric shaft 21 which is an input shaft partially arranged inside the sprocket body 1a and the eccentric shaft 21. A ball bearing 22 which is a bearing provided on the outer periphery of the eccentric shaft 21, and a plurality of rollers 23 provided on the outer periphery of the ball bearing 22 and rotatably held in each internal tooth 5a of the internal gear 5. It is mainly composed of a cage 24 which is integrally provided on the outer peripheral side of the disk-shaped main body 9a of the driven member 9 and allows a plurality of rollers 23 to move in the radial direction while holding the plurality of rollers 23 in the rolling direction.

8A and 8B show an eccentric shaft 21, where A is a side view of the eccentric shaft 21, B is a front view of the eccentric shaft 21, and C is a sectional view taken along line DD of B.

As shown in FIGS. 1 to 3 and 8A to 8C, the eccentric shaft 21 includes an eccentric shaft portion 21a arranged on the outer periphery of the needle bearing 25, which is a bearing provided on the outer periphery of the head portion 14a of the cam bolt 14. It has a large-diameter cylindrical portion 21b, which is a connecting portion of the eccentric shaft portion 21a on the electric motor 12 side.

The eccentric shaft portion 21a is formed in a cylindrical shape whose axial length is longer than the axial length of the needle bearing 25. Further, in the eccentric shaft portion 21a, the wall thickness t in the entire circumferential direction changes in thickness, and the shaft center X is slightly eccentric with respect to the shaft center Y of the cam bolt 14 (see FIGS. 2 and 8C).

The large-diameter cylindrical portion 21b has a uniform wall thickness and is formed in a substantially perfect circle, and is formed to be slightly thicker than the eccentric shaft portion 21a. The large-diameter cylindrical portion 21b projects from the inside of the sprocket body 1a toward the electric motor 12 through the insertion hole 15a of the front cover 15. The large-diameter cylindrical portion 21b constitutes an old dam joint 20 together with the intermediate member 30.

That is, the large-diameter cylindrical portion 21b is formed with a two-sided width-shaped fitting hole 21c into which the tubular base portion 31 of the intermediate member 30 can be fitted from the axial direction.

The large-diameter cylindrical portion 21b is provided with a pair of crescent-shaped convex portions 21f and 21g forming a two-sided width at positions of approximately 180 ° in the circumferential direction of the inner peripheral surface of the fitting hole 21c. Therefore, the inner peripheral surface of the fitting hole 21c is a large diameter portion, and the pair of convex portions 21f and 21g are configured as a small diameter portion. Further, at substantially the center of the upper and lower parts of the pair of convex portions 21f and 21g in FIG. 8B, the pair of key grooves 21d and 21e into which the two transmission keys 33a and 33b of the tubular base portion 31 can be fitted from the rotation axis direction. Is formed. The key grooves 21d and 21e are formed in a rectangular shape similar to the transmission keys 33a and 33b, and the depth thereof is set to be substantially the same as the width of the transmission keys 33a and 33b.

The pair of convex portions 21f and 21g function as suppressing portions for suppressing excessive supply of the lubricating oil injected from the first oil hole 38 of the lubricating oil supply mechanism described later to the electric motor 12 (oldham joint 20). It has become.

The needle bearing 25 is fixed to a plurality of needle rollers 25a that roll on the outer peripheral surface 14e of the head 14a of the cam bolt 14 and a stepped surface formed on the inner peripheral surface of the eccentric shaft portion 21a, and a needle is formed on the inner peripheral surface. It has a cylindrical shell 25b having a plurality of grooves for holding the roller 25a so as to be rollable.

As shown in FIG. 1, the ball bearings 22 are arranged so as to substantially overlap with each other at the radial positions of the needle bearings 25. Further, the ball bearing 22 is composed of an inner ring 22a, an outer ring 22b, a ball 22c interposed between the two wheels 22a and 22b, and a cage 22d for holding the ball 22c.

The inner ring 22a is press-fitted and fixed to the outer peripheral surface of the eccentric shaft portion 21a, whereas the outer ring 22b is in a free state without being fixed in the axial direction. That is, in the outer ring 22b, one end surface on the electric motor 12 side in the axial direction is in a non-contact state with the inner side surface of the front cover 15 via a minute clearance. Further, the other end surface of the outer ring 22b in the axial direction is also in a non-contact state with a minute clearance on the back surface of the disk-shaped main body 9a of the driven member 9 facing the outer ring 22b.

The outer peripheral surface of each roller 23 of the outer ring 22b is in rolling contact with the outer peripheral surface. Further, an annular clearance is formed between the outer peripheral surface of the outer ring 22b and the inner surface of the cage 24. Therefore, the ball bearing 22 can move eccentrically in the radial direction as a whole with the eccentric rotation of the eccentric shaft portion 21a through the clearance.

The cage 24 is formed in a cylindrical shape and is integrally provided on the outer peripheral portion of the disk-shaped main body 9a. That is, the cage 24 projects linearly from the base portion 11a of the journal portion 11 of the disk-shaped main body 9a toward the front cover 15. A predetermined clearance is formed between the tip surface 24a of the cage 24 and the inner surface of the front cover 15.

Further, in the cage 24, a plurality of substantially rectangular roller holding holes 24b for holding the plurality of rollers 23 so as to be rollable are formed along the axial direction. The plurality of roller holding holes 24b are provided at equidistant positions in the circumferential direction of the cage 24, and the tip end side is closed to form an elongated rectangular shape in the front-rear direction. Further, the total number of the roller holding holes 24b (the number of the rollers 23) is smaller than the total number of the internal teeth 5a of the internal gear 5, whereby a predetermined reduction ratio can be obtained. ing.

Each roller 23 is formed of an iron-based metal and is fitted into the internal teeth 5a of the internal gear 5 while moving in the radial direction with the eccentric movement of the ball bearing 22. Further, each roller 23 swings in the radial direction while being guided in the circumferential direction by both side edges of the roller holding holes 24b.

Further, the speed reducer 13 and the Oldham joint 20 described above are provided with lubricating oil internally via a lubricating oil supply mechanism.

That is, as shown in FIGS. 1 and 3, the lubricating oil supply mechanism is provided from the oil supply passage 34 formed in the internal axial direction of the camshaft 2 and the center of the bottom surface of the tool hole 14d of the head portion 14a of the cambolt 14. It has an oil passage hole 35 formed through the shaft portion 14b along the internal axial center direction, and an oil pump 36 for supplying lubricating oil to the oil supply passage 34.

The oil supply passage 34 is formed long along the internal axial center direction of the camshaft 2, and is also used as a means for supplying lubricating oil to a plurality of bearings (not shown in the figure) of the camshaft 2. Further, the oil supply passage 34 communicates with the discharge passage 36a of the oil pump 36 via a supply hole 34a formed along the radial direction of the camshaft 2.

As shown in FIGS. 1 and 3, the oil passage hole 35 includes a part of the head 14a of the cam bolt 14, a main passage hole 37 formed in the internal axial direction of the shaft portion 14b, and the internal axial direction of the head 14a. The first oil hole 38 is formed in the above and communicates with the other end 37b on the downstream side of the main passage hole 37, and extends radially from the axial center of the head 14a and communicates with the other end 37b of the main passage hole 37. It is provided with a second oil hole 39.

The main passage hole 37 is formed linearly along the axis of the cam bolt 14, and one end portion 37a on the upstream side is opened in the oil supply passage 34 of the camshaft 2. On the other hand, the other end 37b on the downstream side is located inside the head 14a and is connected to the first and second oil holes 38 and 39. Further, the main passage hole 37 has a uniform inner diameter of about 2 mm.

The upstream end of the first oil hole 38 is continuously connected to the other end 37b of the main passage hole 37 from the axial direction, while the first opening 38a at the downstream end opens into the tool hole 14d. The first opening 38a directs the tip portion 17a of the motor shaft 17, which will be described later, from the axial direction, and supplies lubricating oil to the old dam joint 20. Further, the first oil hole 38 has an inner diameter set to about 1 mm and functions as an orifice narrowed down from the main passage hole 37. Therefore, as shown by the arrow in FIG. 2, the lubricating oil that has flowed into the main passage hole 37 is applied from the first opening 38a of the first oil hole 38 to the tip portion 17a of the motor shaft 17, that is, the tool hole 14d. It is injected and diffused from here to be supplied to the friction generating portion of the Oldham joint 20 and the speed reducer 13.

The upstream end of the second oil hole 39 is radially connected to the other end 37b of the main passage hole 37, while the second opening 39a at the downstream end opens inside the speed reducer 13. Specifically, the second opening 39a is radially oriented toward one end of the shell 25b of the needle bearing 25 in the axial direction. Further, the inner diameter of the second oil hole 39 is set to about 1 mm like the first oil hole 38, and the second oil hole 39 functions as an orifice narrowed down from the main passage hole 37 of about 2 mm. Therefore, the lubricating oil that has flowed into the main passage hole 37 is jetted from the second opening 39a of the second oil hole 39 to the speed reducer 13. That is, the lubricating oil injected from the second opening 39a is supplied to the entire speed reducer 13 including the needle bearing 25, the ball bearing 22, the cage 24, and the like.

Further, the lubricating oil that has flowed into the speed reducer 13 from the second oil hole 39 passes through the inside of the ball bearing 22 and the cage 24 on the outer peripheral side due to the centrifugal force during driving, and from here, the bearing recess 10 And the journal section 11. That is, the lubricating oil is supplied to lubrication by passing between both end faces and outer peripheral surfaces of the journal portion 11 and the inner side surface 10b and the slide bearing surface 10a of the bearing recess 10.

The oil pump 36 is a general pump such as a trochode, and the discharge passage 36a communicates with a main oil gallery (not shown) that mainly supplies lubricating oil that lubricates the inside of an internal combustion engine.

The control unit detects the current engine operating state based on information signals from various sensors such as the crank angle sensor, air flow meter, water temperature sensor, and accelerator opening sensor (not shown in the figure), and controls the engine based on this. Is going. Further, the control unit energizes the coil portion to control the rotation of the motor shaft 17 based on the respective information signals and the rotation position detection mechanism, and the speed reducer 13 determines the relative rotation phase of the camshaft 2 with respect to the timing sprocket 1. It is designed to be controlled.
[Action and effect of this embodiment]
Hereinafter, the operation of the valve timing control device in this embodiment will be described.

First, when the timing sprocket 1 rotates via the timing chain with the rotational drive of the crankshaft of the engine, this rotational force is transmitted to the internal gear 5. The rotational force of the internal gear 5 is transmitted from each roller 23 to the camshaft 2 via the cage 24 and the driven member 9. As a result, the drive cam of the camshaft 2 opens and closes each intake valve.

During a predetermined engine operation after the engine is started, the control current from the control unit is applied to the coil portion of the electric motor 12 to drive the motor shaft 17 in forward and reverse rotation. The rotational force of the motor shaft 17 is transmitted to the eccentric shaft 21 via the oldham joint 20, and the decelerated rotational force is transmitted to the camshaft 2 by the operation of the speed reducer 13.

As a result, the camshaft 2 rotates forward and reverse relative to the timing sprocket 1 to convert the relative rotation phase. Therefore, each intake valve is controlled by converting the opening / closing timing to the advance angle side or the retard angle side.

In this way, by continuously converting the opening / closing timing of the intake valve to the advance angle side or the retard angle side, it is possible to improve the engine performance such as the fuel efficiency and output of the engine.

Then, in the present embodiment, the inside of the old dam joint 20 and the speed reducer 13 can be effectively lubricated by the lubricating oil supply function.

That is, a part of the lubricating oil discharged to the discharge passage 36a by the drive of the oil pump 36 is supplied to the inside of the engine from the main oil gallery, but the other part is supplied to the oil supply passage 34 from the supply hole 34a. NS.

As shown by the arrows in FIGS. 1 and 3, the lubricating oil supplied to the oil supply passage 34 flows into the oil passage hole 35 from the one end portion 37a, and flows into the oil passage hole 35 from the other end portion 37b to the first oil hole 38 and the second oil hole 38. Divide into the oil hole 39. The lubricating oil in the first oil hole 38 is jetted from the first opening 38a through the tool hole 14d to the tip portion 17a of the motor shaft 17 from the axial direction, collides with the oil, and scatters. The scattered lubricating oil is supplied to the inside of the Oldham joint 20. That is, it is supplied to a friction generating portion such as between the inner peripheral surface of the tubular base portion 31 and the tip portion 17a of the motor shaft 17, or between the transmission keys 33a and 33b and the key grooves 21d and 21e of the eccentric shaft 21. Therefore, the entire friction generating part is effectively lubricated. As a result, the lubrication performance of the Oldham joint 20 is improved and smooth operation is always obtained.

Further, as described above, a part of the lubricating oil injected from the first oil hole 38 is supplied to one end side of the needle bearing 25 on the axial direction of the electric motor 12 through the gap C by centrifugal force. The other part wraps around the front end side of the eccentric shaft 21 and is supplied to the axial front end side of the ball bearing 22. As a result, the needle bearing 25 and the ball bearing 22 are lubricated.

Further, the lubricating oil injected from the first oil hole 38 is suppressed from being scattered from the eccentric shaft 21 to the outside by the biconvex portions 21f and 21g of the eccentric shaft 21. Therefore, it is efficiently supplied to the Oldham joint 20 and the speed reducer 13.

On the other hand, the lubricating oil that has flowed into the second oil hole 39 from the other end of the oil passage hole 35 is injected from the second opening 39a as shown by the arrow in FIG. 2, and is the other end in the axial direction of the needle bearing 25. It is supplied to the department side. Further, it is supplied from here to the rear end side in the axial direction of the ball bearing 22 by centrifugal force or the like during driving, and is also supplied between each roller holding hole 24b of the cage 24 and each roller 23. Further, this lubricating oil is supplied between the slide bearing surface 10a of the bearing recess 10 and the outer peripheral surface of the journal portion 11 by centrifugal force.

Therefore, the lubricity of the needle bearing 25, the ball bearing 22, the space between each roller holding hole 24b and each roller 23, the inner surface of the bearing recess 10 and the outer surface of the journal portion 11 as a whole is improved.

Therefore, the lubricity to the speed reducer 13 is further promoted, and the lubricity to the bearing between the driven member 9 and the sprocket 1 is also improved.

As shown by the arrow, the lubricating oil supplied from the first and second oil holes 38 and 39 to the oldam joint 20 and the speed reducer 13 passes through the gap C and the fitting hole 21c by centrifugal force to the front. It is discharged into the oil pan 45 from the insertion hole 15a of the cover 15.

Further, the lubricating oil supplied from the oil passage hole 35 to the first oil hole 38 and the second oil hole 39 is put into an injection state by the drawing function of both oil holes 38 and 39, so that an excessive supply amount is suppressed. Will be done.

Moreover, the lubricating oil injected from the first oil hole 38 is suppressed from excessive diffusion by the inner peripheral surface of the tool hole 14d and the biconvex portions 21f and 21g of the fitting hole 21c. Therefore, the lubricating oil can be efficiently supplied to the Oldham joint 20 and the speed reducer 13.

Further, in the present embodiment, since the oil passage hole 35 of the lubricating oil supply mechanism is formed not inside the camshaft 2 but inside the cam bolt 14, the molding work is simplified and the work cost can be reduced.

That is, the camshaft 2 is merely formed with an existing oil supply passage 34 for lubricating the bearing of the camshaft 2. In other words, the oil passage hole 35 for lubricating the speed reducer 13 and the like is formed by the main passage hole 37a in the internal axial direction of the cam bolt 14 and the first and second oil holes 38 and 39 in the radial direction. There is. That is, since the oil passage hole 35 can be formed in the cam bolt 14 simply by drilling, for example, the machining work can be facilitated and the machining cost can be reduced.

Further, since the second oil hole 39 is formed inside the head portion 14a instead of the shaft portion 14b of the cam bolt 14, it is possible to suppress a decrease in the strength of the cam bolt 14.

Further, in the present embodiment, when the cam bolt 14 is fastened to the camshaft 1 via the bolt insertion hole 9c of the driven member 9, the driven member 9 and the camshaft 2 are coaxial (alignment) by the intermediate shaft portion 14 g. Can be obtained.

That is, the intermediate shaft portion 14g is inserted and fitted into the bolt insertion hole 9c in a substantially intermediate fit state, and the female screw portion 2d and the male screw portion 14c are fastened to maintain the coaxiality between the driven member 9 and the camshaft 2. It will be possible to obtain.

Further, when the cam bolt 14 is tightened with a predetermined tightening torque, the seat surface 14f of the head 14a becomes the peripheral surface of the hole on the electric motor 12 side of the bolt insertion hole 9c of the driven member 9 (the peripheral surface of the disk-shaped main body 9a). Press on. Even if the seat surface 14f side of the head 14a is buckled and deformed in the radial direction due to this pressure, the influence of this deformation on the tightening torque is small. Therefore, it is possible to obtain a desired fastening torque by the cam bolt 14.

Further, the bolt insertion hole 9c of the driven member 9 is formed to have a relatively large diameter in order to insert and fit the intermediate shaft portion 14g having an inner diameter larger than the outer diameter of the shaft portion 14b (male screw portion 14c). Therefore, the cam bolt 14 can be inserted into the bolt insertion hole 9c with a margin through the gap between the two 9c and 14b. Therefore, it is possible to prevent the male screw portion 14c from interfering with the hole edge of the bolt insertion hole 9c and being damaged at the time of this insertion.

Further, the tapered portion 14h provided on the tip end side of the intermediate shaft portion 14g functions as a guide when the shaft portion 14b of the cam bolt 14 is inserted into the bolt insertion hole 9c. Therefore, the work of inserting the cam bolt 14 into the bolt insertion hole 9c becomes easy.

Further, the arcuate groove 14i formed between the head portion 14a and the intermediate shaft portion 14g can suppress the occurrence of stress concentration between the head portion 14a and the intermediate shaft portion 14g when the cam bolt 14 is tightened.

Further, in the present embodiment, since the outer peripheral surface 14e of the head 14a is subjected to high frequency quenching to have high hardness, the following effects can be obtained.

That is, a reverse input acts on the cam bolt 14 due to the positive and negative alternating torque of the camshaft 2 generated during engine drive, and a radial load is input to the outer peripheral surface 14e of the head 14a. As a result, the needle bearing 25 may interfere with the outer peripheral surface 14e of the head portion 14a. However, since the outer peripheral surface 14e of the head 14a has a high hardness, the occurrence of damage can be suppressed.

On the other hand, since the hardness of the seat surface 14f of the head portion 14a is lower than that of the outer peripheral surface 14e, it is possible to sufficiently secure the fastening force of the cam bolt 14 due to its high toughness.

Further, the tip portion 17a (including the stopper member 19) of the motor shaft 17 of the electric motor 12 can be inserted into the tool hole 14d of the cam bolt 14 from the direction of the rotation axis. Therefore, when the motor shaft 17 or the camshaft 2 (driven member 9) moves in the direction of the rotation axis due to vibration of the engine or the like, the tip portion 17a of the motor shaft 17 enters the tool hole 14d and absorbs this movement. can. This makes it possible to shorten the axial distance between the motor shaft 17 and the cam bolt 14 as much as possible.

As a result, the valve timing control device can be shortened in length in the axial direction as a whole, so that the device can be miniaturized and the mountability in the engine room is improved.

Further, the intermediate member 30 can move in the radial direction with respect to the motor shaft 17 via the two facing surfaces 32a and 32b of the through hole 32 and the width across flat portions 17b and 17c of the motor shaft tip portion 17a. ing. Further, the eccentric shaft 21 can move in the radial direction orthogonal to the radial movement of the intermediate member 30 via the two key grooves 21d and 21e and the two transmission keys 33a and 33b of the intermediate member 30.

Therefore, it is possible to effectively absorb the manufacturing error of the Oldham joint 20 and the radial error of the motor shaft 17 and the eccentric shaft 21 during rotation. As a result, the rotational force of the motor shaft 17 can be efficiently transmitted to the driven member 9.

Further, in the present embodiment, when a force (thrust load F1, F2) in the inclination direction with respect to the driven member 9 is generated on the sprocket 1 during rotational drive (see FIG. 1), the thrust loads F1 and F2 are transferred by the journal portion 11. I can take it. Therefore, it is possible to suppress the tilt of the sprocket 1.

That is, when the sprocket 1 tries to tilt in one direction, the inner side surface 10b of the bearing recess 10 abuts on one end surface of the journal portion 11 to receive and regulate the thrust load F1 in one direction.

Further, when the sprocket 1 tries to tilt in the other direction, the inner side surface 8f of the inner peripheral portion 8b of the holding plate 8 abuts on the other end surface of the journal portion 11 to receive and regulate the thrust load F2 in the other direction.

As a result, the sprocket 1 is effectively suppressed from being tilted with respect to the driven member 9.
[Second Embodiment]
FIG. 9 shows a second embodiment of the present invention, in which the motor shaft 17 of the electric motor 12 and the cylindrical base 31 of the Oldham joint 20 are axially separated from the front end surface of the head portion 14a of the cam bolt 14, and the gap C is shown. The axial width of is large.

Further, the second oil hole 39 of the oil passage hole 35 is abolished and only the first oil hole 38 is used. Other configurations are the same as in the first embodiment.

Therefore, the lubricating oil pumped from the oil pump 36 to the main passage hole 37a of the oil passage hole 35 is injected axially from the first oil hole 38 to the tip portion 17a of the motor shaft 17 as shown by the arrow in FIG. Will be done. The injected lubricating oil collides with the tip portion 17a and scatters to lubricate the inside and outside of the tubular base portion 31, that is, the old dam joint 20.

On the other hand, a part of the injected lubricating oil is supplied to one end of the needle bearing 25 in the axial direction through the gap C by centrifugal force or the like, and the ball bearing on the outer peripheral side is lubricated inside the needle bearing 25. It is supplied to the inside of 22. The lubricating oil is further supplied from here between each roller holding hole 24b on the outer peripheral side and each roller 23, and is also supplied to the journal portion 11. Therefore, the friction generating portion such as around the speed reducer 13 and the journal portion 11 is effectively lubricated.

The lubricating oil that lubricated the Oldham joint 20 is discharged into the oil pan 45 as it is.

Other functions and effects are the same as those of the first embodiment, but in this embodiment, since the second oil hole 39 is abolished, the processing work of the oil passage hole 35 becomes easier and the cost can be reduced. ..
[Third Embodiment]
FIG. 10 shows a third embodiment, in which a pair of passage grooves 40, 41 are formed on the outer peripheral surface of the shaft portion 14b of the cam bolt 14, and a driven member is formed, instead of forming an oil passage hole inside the cam bolt 14. An L-shaped communication hole 42 is formed in the inner peripheral portion of 9.

That is, the pair of passage grooves 40 and 41 are located at approximately 180 ° in the circumferential direction of the shaft portion 14b, and cross the male screw portion 14c on the outer peripheral surface of the shaft portion 14b in a straight line along the axial direction. It is provided in.

Further, in the camshaft 2, an annular groove groove 43 is formed on the inner peripheral surface of the insertion hole 2c on the one end portion 2a side.

In each of the passage grooves 40 and 41, one end portions 40a and 41a on the upstream side are open to the oil supply passage 34 of the camshaft 2, while the other end portions 40b and 41b on the downstream side are open to the groove groove 43. ..

The communication hole 42 has a radial hole 42a provided on the bottom surface of the fitting groove 9d of the driven member 9 so as to extend radially with respect to the rotation axis center, and a shaft formed through the disk-shaped main body 9a in the rotation axis direction. It has a direction hole 42b and.

The radial hole 42a is formed in an elongated groove shape, with one inner end communicating with one end of the groove groove 43 and the other outer end communicating with the axial hole 42b.

The axial hole 42b has one end opposite to the radial hole 42a open to the other end of the needle bearing 25 in the axial direction along the axial direction.

Therefore, the lubricating oil pumped from the oil supply passage 34 to the passage grooves 40 and 41 flows into the communication hole 42 through the groove groove 43 as shown by an arrow in the figure. Then, the lubricating oil that has flowed into the radial hole 42a of the communication hole 42 is injected from the axial hole 42b to the other end side of the needle bearing 25. After that, the lubricating oil is supplied to the outer ball bearing 22 by centrifugal force or the like, further supplied between the roller holding hole 24b and the roller 23, and further supplied around the journal portion 11. Therefore, each friction generating portion such as the speed reducer 13 is effectively lubricated.

Therefore, the same action and effect as those of each of the above-described embodiments can be obtained. In particular, in this embodiment, since the passage grooves 40 and 41 are simply formed on the outer periphery of the shaft portion 14b of the cam bolt 14, this processing work is easy and the processing cost can be reduced.
[Fourth Embodiment]
FIG. 11 shows a fourth embodiment, and the basic configuration is the same as that of the second embodiment, but the structure of the front cover 15 which is a cover member is changed.

As shown in FIG. 12, the front cover 15 has an outer peripheral portion 15c formed in a flat annular flange shape, but the inner peripheral portion 15d around the central insertion hole 15a bulges toward the electric motor 12. It is deformed. That is, the inner peripheral portion 15d is bent and deformed into a vertical cross-sectional crank shape so as to project in the direction of the electric motor 12, and the entire front cover 15 is formed in a bowl shape.

The inner peripheral portion 15d is formed in a conical shape, and the front end portion 15d on the insertion hole 15a side covers the outer periphery of the large-diameter cylindrical portion 21b of the eccentric shaft 21 via a predetermined gap C1.

Therefore, the lubricating oil pumped from the oil pump 36 to the main passage hole 37a of the oil passage hole 35 is injected axially from the first oil hole 38 to the tip portion 17a of the motor shaft 17 as shown by the arrow in FIG. Will be done. The injected lubricating oil collides with the tip portion 17a and scatters to lubricate the inside and outside of the tubular base portion 31, that is, the old dam joint 20.

On the other hand, a part of the injected lubricating oil is supplied to one end of the needle bearing 25 in the axial direction through the gap C by centrifugal force or the like, and the ball bearing on the outer peripheral side is lubricated inside the needle bearing 25. It is supplied to the inside of 22. Further, the lubricating oil is supplied from here between each roller holding hole 24b on the outer peripheral side and each roller 23, and is also supplied to the journal portion 11. Therefore, the friction generating portion such as around the speed reducer 13 and the journal portion 11 is effectively lubricated.

Further, a part of the lubricating oil supplied to one end side of the needle bearing 25 is guided toward the ball bearing 22 through the gap C1 by centrifugal force. As a result, the lubricity around the speed reducer 13 such as the ball bearing 22 and the roller 23 and the journal portion 11 is further improved.

In this embodiment, since the inner peripheral portion 15b of the front cover 15 functions as a guide and a collector of the lubricating oil, the supply amount of the lubricating oil of the speed reducer 13 and the like is increased, and further higher lubricating performance can be obtained.

The present invention is not limited to the configuration of each of the above embodiments, and the speed reducer 13 may be, for example, a planetary gear device.

Further, the first and second oil holes 38 and 39 of each embodiment can be formed to have the same inner diameter as the oil passage hole 35, and conversely, the oil passage hole 35 is formed into the first and second oil holes 38. It is also possible to have the same orifice-shaped small diameter as 39.

As the valve timing control device for the internal combustion engine based on the embodiment described above, for example, the one described below can be considered.

That is, as a preferred embodiment in the present invention, a drive rotating body to which the rotational force from the crankshaft is transmitted, a driven rotating body provided so as to be rotatable relative to the driving rotating body and fixed to the camshaft, and the like. A speed reducer provided between the drive rotating body and the driven rotating body that rotates the driven rotating body relative to the driving rotating body by rotating the input shaft, and the input shaft is rotated via a joint. An electric motor having a motor shaft to be made to be driven, and a cam bolt for connecting the driven rotating body to the camshaft, which communicates with a supply passage for supplying lubricating oil to the inside of the internal combustion engine, and is at least one of the joint and the speed reducer. The cambolt has an oil passage hole inside which can supply lubricating oil.

More preferably, the joint has an intermediate member rotatably held to the motor shaft and a connecting portion provided on the input shaft and rotatably connected to the intermediate member. ..

More preferably, the oil passage hole has an opening on the downstream side that opens facing the joint in the axial direction.

According to the aspect of the present invention, since the opening of the oil passage hole opens in the joint from the axial direction, the lubricity to the joint is improved.

More preferably, the input shaft has a suppressing portion that suppresses the supply of excess lubricating oil from the oil passage hole to the electric motor side.

According to the aspect of the present invention, the lubricating oil flowing out from the oil passage hole to the joint side can be suppressed from being scattered to the outside by the restraining portion, so that the lubricity to the joint and the speed reducer is improved.

More preferably, the restraining portion is provided on the inner circumference of the input shaft, and is a large-diameter portion provided on the camshaft side in the axial direction and a motor shaft side in the axial direction rather than the large-diameter portion. Therefore, at least a part thereof is composed of a small diameter portion formed to have a diameter smaller than the inner diameter of the large diameter portion.

More preferably, the cam bolt has a head whose seat surface can abut on the driven rotating body from the axial direction, and a bolt insertion hole formed in the driven rotating body by extending from the seat surface toward the camshaft. The oil passage hole has a shaft portion to be inserted into the shaft portion and a male screw portion formed on the outer peripheral surface of the shaft portion and screwed to a female screw portion formed in the internal axial direction of the camshaft. , The main passage hole provided mainly from the tip end side of the shaft portion of the cam bolt along the internal axial direction, and the main passage hole provided continuously along the internal axial direction of the head portion in the tip end side. It has the opening and has a first oil hole whose inner diameter is smaller than the inner diameter of the main passage hole.

According to the aspect of the present invention, since the first oil hole exerts a drawing function, the lubricating oil that has flowed into the main passage hole is supplied from the first oil hole to the joint in an injected state. Further, the squeezing function of the first oil hole suppresses the excessive supply of lubricating oil.

More preferably, the first oil hole is opened in a tool hole provided in the head of the cam bolt.

According to the aspect of the present invention, the lubricating oil injected from the first oil hole through the opening diffuses in the tool hole, so that it can be supplied to the entire joint.

More preferably, the cam bolt has a head whose seat surface can abut on the driven rotating body from the axial direction, and a bolt insertion hole formed in the driven rotating body by extending from the seat surface toward the camshaft. The oil passage hole has a shaft portion to be inserted into the shaft portion and a male screw portion formed on the outer peripheral surface of the shaft portion and screwed to a female screw portion formed in the internal axial direction of the camshaft. A main passage hole provided mainly along the internal axial direction from the tip end side of the shaft portion of the cam bolt, and a main passage hole provided along the internal radial direction of the head portion, while one end communicates with the main passage hole. The other end is provided with a second oil hole having a second opening that opens toward the speed reducer.

According to the aspect of the present invention, the lubricating oil that has flowed into the second oil hole from the main passage hole is directly supplied to the speed reducer from the second opening, so that the lubrication performance of the speed reducer is improved. Further, since the second oil hole is formed in the head portion of the cam bolt having high rigidity, it is possible to suppress a decrease in the strength of the cam bolt as compared with the case where the second oil hole is formed in the shaft portion or the male screw portion of the shaft portion.

More preferably, the second opening opens radially inward of the speed reducer.

According to the aspect of the present invention, the lubricating oil flowing into the second oil hole from the main passage hole can be supplied to the speed reducer from the radial inside through the second opening by utilizing the discharge pressure and the centrifugal force. , Can be sufficiently supplied to the reducer.

More preferably, a bearing forming a part of the speed reducer is provided between the outer peripheral surface of the head of the cam bolt and the inner peripheral surface of the input shaft, and the second opening of the second oil hole is , The bearing is arranged closer to the contact portion between the seat surface of the head and the driven rotating body than the central position in the axial direction of the bearing.

According to the aspect of the present invention, the lubricating oil that has flowed into the second oil hole from the main passage hole can be directly supplied to the bearing of the speed reducer from the second opening. Therefore, it is possible to supply the lubricating oil to the bearing more efficiently than when the lubricating oil is supplied from the tip side of the head.

More preferably, the speed reducer has an internal gear provided on the inner circumference of the drive rotating body, a bearing arranged on the outer periphery of the input shaft, and between the outer circumference of the bearing and the internal teeth of the internal gear. The bearing and the oil passage hole are provided with a plurality of rolling elements arranged in the above and a cage integrally provided with the driven rotating body and holding the plurality of rolling elements at predetermined intervals in the circumferential direction. Communicating.

According to the aspect of the present invention, the lubricating oil supplied to the oil passage hole can be positively supplied to the bearing of the speed reducer through the oil passage hole, so that the lubrication performance of the bearing can be improved. ..

More preferably, the cam bolt has a head whose seat surface can abut on the driven rotating body from the axial direction, and a bolt insertion hole formed in the driven rotating body by extending from the seat surface toward the camshaft. The oil passage hole has a shaft portion to be inserted into the shaft portion and a male screw portion formed on the outer peripheral surface of the shaft portion and screwed to a female screw portion formed in the internal axial direction of the camshaft. , The opening at the downstream end opens to the electric motor side of the head, and the bearing has one end portion on the electric motor side in the axial direction than the front end portion on the electric motor side in the axial direction of the head. It is arranged near the electric motor.

According to the aspect of the present invention, the lubricating oil flowing out from the downstream opening through the oil passage hole is radially scattered by the rotational centrifugal force and passes through the front end surface of the head, and one end portion of the bearing. It will be collected in. This improves the lubricity of the bearing.

More preferably, the cam bolt is formed on the driven rotating body by extending from the seat surface of the head toward the camshaft and a head having a seat surface capable of contacting the driven rotating body from the axial direction. It has a shaft portion to be inserted into the bolt insertion hole, and a male screw portion formed on the outer peripheral surface of the shaft portion and screwed to a female screw portion formed in the internal axial direction of the camshaft. The oil passage hole has an opening at the downstream end that opens toward the electric motor side of the head, and the drive rotating body covers at least a part of the end portion of the input shaft on the electric motor side in the axial direction. It has a member.

According to the aspect of the present invention, the lubricating oil flowing out from the opening at the downstream end through the oil passage hole is scattered from the inside of the head to the outer peripheral side by centrifugal force, but a part of the scattered lubricating oil. Is collected on the inner surface of the cover member and supplied to the inside of the reducer. This improves the lubricity of parts such as bearings and rollers of the reducer.

As another preferred embodiment, a drive rotating body to which the rotational force from the crank shaft is transmitted, a driven rotating body provided so as to be rotatable relative to the driving rotating body and fixed to the cam shaft, and the driving rotation. A speed reducer provided between the body and the driven rotating body that rotates the driven rotating body relative to the driving rotating body by rotating the input shaft, and a motor shaft that rotates the input shaft via a joint. A cam bolt for connecting the driven rotating body to the cam shaft, and a shaft portion provided with a male screw portion to be screwed into a female screw hole provided in the internal axial direction of the cam shaft, and the male screw portion. The cam bolt provided along the axial direction of the outer peripheral surface of the shaft portion including the above and having a passage groove through which lubricating oil flows, and the passage groove provided in the driven rotating body and the speed reducer communicate with each other. It is equipped with a communication hole.

According to the aspect of the present invention, the lubricating oil flowing into the passage groove formed on the outer peripheral surface of the shaft portion of the cam bolt can be supplied to the speed reducer through the communication hole.

In particular, in the present invention, the molding work is simple because a passage groove along the axial direction is simply formed on the outer peripheral surface of the shaft portion (including the male screw portion) of the cam bolt. Therefore, the molding workability is improved and the cost can be reduced.

More preferably, the cam bolt has a head whose seat surface abuts on the driven rotating body from the axial direction, and a bearing is provided between the outer periphery of the head and the inner circumference of the input shaft to communicate with the cam bolt. The hole is located at the same position as the bearing at the tip position in the radial direction from the rotation axis of the driven rotating body, or is located inside the bearing.

According to the aspect of the present invention, since the tip position of the communication hole is located at the same level as or inside the bearing, it is easy to lubricate the bearing.

More preferably, the passage groove is provided across the thread of the male threaded portion.

1 ... Timing sprocket (drive rotating body), 1a ... Sprocket body, 1b ... Gear part (external teeth), 2 ... Cam shaft, 2a ... One end, 3 ... Phase change mechanism, 8 ... Holding plate, 9 ... Driven member ( Driven rotating body), 9a ... Disc-shaped body, 9b ... Fixed end, 11 ... Journal, 12 ... Electric motor, 13 ... Reducer, 14 ... Cam bolt, 14a ... Head, 14b ... Shaft, 14c ... Male thread , 14e ... outer peripheral surface, 14f ... bearing surface, 14g ... intermediate shaft portion, 15 ... front cover (cover member), 15a ... insertion hole, 15c ... inner peripheral portion, 21 ... eccentric shaft (input shaft), 21a ... eccentric shaft Part, 21b ... Large diameter cylindrical part (connecting part), 21c ... Fitting hole (large diameter part, restraining part), 21g / 21f ... Convex part (small diameter part, restraining part), 22 ... Ball bearing (bearing), 23 ... Roller, 24 ... Cage, 24b ... Roller holding hole, 25 ... Needle bearing (bearing), 30 ... Intermediate member, 31 ... Cylindrical base, 34 ... Oil supply passage, 37 ... Oil passage hole 35a ... Main passage hole, 38 ... 1st oil hole, 38a ... 1st opening, 39 ... 2nd oil hole, 39a ... 2nd opening, 40.41 ... passage groove, 42 ... communication hole, 42a ... radial hole, 42b ... axial direction Hole.

Claims (16)

A drive rotating body to which the rotational force from the crankshaft is transmitted,
A driven rotating body provided so as to be rotatable relative to the driving rotating body and fixed to the camshaft, and a driven rotating body.
A speed reducer provided between the driven rotating body and the driven rotating body, which rotates the driven rotating body relative to the driving rotating body by rotating the input shaft.
An electric motor having a motor shaft that rotates the input shaft via a joint,
An oil passage that is a cambolt that connects the driven rotating body to the camshaft and that communicates with a supply passage that supplies lubricating oil to the inside of the internal combustion engine and can supply lubricating oil to at least one of the joint and the speed reducer. With the cam bolt having a hole inside,
A valve timing control device for an internal combustion engine, which is characterized by being equipped with. In the valve timing control device for an internal combustion engine according to claim 1.
The joint is an internal combustion engine characterized by having an intermediate member integrally rotatably held by the motor shaft and a connecting portion provided on the input shaft and integrally rotatably connected to the intermediate member. Valve timing control device. In the valve timing control device for an internal combustion engine according to claim 2.
A valve timing control device for an internal combustion engine, wherein the oil passage hole has an opening on the downstream side that opens facing the joint in the axial direction. In the valve timing control device for an internal combustion engine according to claim 3.
The valve timing control device for an internal combustion engine, characterized in that the input shaft has a suppression unit that suppresses the supply of lubricating oil from the oil passage hole to the electric motor side. In the valve timing control device for an internal combustion engine according to claim 4.
The restraining portion is provided on the inner circumference of the input shaft, and has at least one large-diameter portion provided on the camshaft side in the axial direction and the motor shaft side in the axial direction from the large-diameter portion. A valve timing control device for an internal combustion engine, characterized in that the portion is composed of a small diameter portion formed to have a diameter smaller than the inner diameter of the large diameter portion. In the valve timing control device for an internal combustion engine according to claim 3.
The cam bolt is inserted into a head whose seat surface can abut on the driven rotating body from the axial direction and a bolt insertion hole formed in the driven rotating body extending from the seat surface toward the camshaft. It has a shaft portion and a male screw portion formed on the outer peripheral surface of the shaft portion and screwed to a female screw portion formed in the internal axial direction of the camshaft.
The oil passage hole is continuously provided in the main passage hole provided mainly from the tip end side of the shaft portion of the cam bolt along the internal axial direction and in the main passage hole along the internal axial direction of the head. A first oil hole having the opening on the tip side and having an inner diameter smaller than the inner diameter of the main passage hole.
A valve timing control device for an internal combustion engine, which is characterized by being equipped with. In the valve timing control device for an internal combustion engine according to claim 6.
The valve timing control device for an internal combustion engine, wherein the first oil hole is open in a tool hole provided in the head of the cam bolt. In the valve timing control device for an internal combustion engine according to claim 1.
The cam bolt is inserted into a head whose seat surface can abut on the driven rotating body from the axial direction and a bolt insertion hole formed in the driven rotating body extending from the seat surface toward the camshaft. It has a shaft portion and a male screw portion formed on the outer peripheral surface of the shaft portion and screwed to a female screw portion formed in the internal axial direction of the camshaft.
The oil passage hole is mainly provided along the internal axial direction from the tip end side of the shaft portion of the cam bolt, and is provided along the internal radial direction of the head, and one end thereof is the main passage hole. A second oil hole having a second opening at which the other end opens toward the speed reducer, while communicating with the speed reducer.
A valve timing control device for an internal combustion engine, which is characterized by being equipped with. In the valve timing control device for an internal combustion engine according to claim 8.
The valve timing control device for an internal combustion engine, wherein the second opening is open inward in the radial direction of the speed reducer. In the valve timing control device for an internal combustion engine according to claim 9.
A bearing forming a part of the speed reducer is provided between the outer peripheral surface of the head of the cam bolt and the inner peripheral surface of the input shaft.
The second opening of the second oil hole is arranged closer to the contact portion between the seat surface of the head and the driven rotating body than the central position in the axial direction of the bearing. Valve timing control device. In the valve timing control device for an internal combustion engine according to claim 1.
The speed reducer is arranged between an internal gear provided on the inner circumference of the drive rotating body, a bearing arranged on the outer periphery of the input shaft, and an outer circumference of the bearing and an internal tooth of the internal gear. It has a plurality of rolling elements and a cage provided integrally with the driven rotating body and holding the plurality of rolling elements at predetermined intervals in the circumferential direction.
A valve timing control device for an internal combustion engine, characterized in that the bearing and the oil passage hole communicate with each other. In the valve timing control device for an internal combustion engine according to claim 11.
The cam bolt is inserted into a head whose seat surface can abut on the driven rotating body from the axial direction and a bolt insertion hole formed in the driven rotating body extending from the seat surface toward the camshaft. It has a shaft portion and a male screw portion formed on the outer peripheral surface of the shaft portion and screwed to a female screw portion formed in the internal axial direction of the camshaft.
In the oil passage hole, the opening at the downstream end opens to the electric motor side of the head.
The bearing is characterized in that one end on the electric motor side in the axial direction is arranged closer to the electric motor than the front end on the electric motor side in the axial direction of the head of the internal combustion engine. Control device. In the valve timing control device for an internal combustion engine according to claim 1.
The cam bolt has a head having a seat surface capable of contacting the driven rotating body from the axial direction, and a bolt insertion hole formed in the driven rotating body extending from the seat surface of the head toward the camshaft. It has a shaft portion to be inserted into the shaft portion and a male screw portion formed on the outer peripheral surface of the shaft portion and screwed to a female screw portion formed in the internal axial direction of the camshaft.
In the oil passage hole, the opening at the downstream end opens to the electric motor side of the head.
The drive rotating body is a valve timing control device for an internal combustion engine, characterized in that at least a part thereof has a cover member that covers an end portion of the input shaft on the side of the electric motor in the axial direction. A drive rotating body to which the rotational force from the crankshaft is transmitted,
A driven rotating body provided so as to be rotatable relative to the driving rotating body and fixed to the camshaft, and a driven rotating body.
A speed reducer provided between the driven rotating body and the driven rotating body, which rotates the driven rotating body relative to the driving rotating body by rotating the input shaft.
An electric motor having a motor shaft that rotates the input shaft via a joint,
A cambolt for connecting the driven rotating body to the camshaft, the shaft portion provided with a male screw portion to be screwed into the female screw hole provided in the internal axial direction of the camshaft, and the outer periphery of the shaft portion including the male screw portion. The cam bolt, which is provided along the axial direction of the surface and has a passage groove through which the lubricating oil flows.
A valve timing control device for an internal combustion engine provided in the driven rotating body and provided with a communication hole for communicating the passage groove and the speed reducer. In the valve timing control device for an internal combustion engine according to claim 14.
The cam bolt has a head whose seat surface abuts on the driven rotating body from the axial direction.
A bearing is provided between the outer circumference of the head and the inner circumference of the input shaft.
The valve timing control device for an internal combustion engine, characterized in that the communication hole has a tip position radially from the rotation axis of the driven rotating body at the same position as the bearing or located inside the bearing. In the valve timing control device for an internal combustion engine according to claim 15.
The valve timing control device for an internal combustion engine, characterized in that the passage groove is provided across the thread of the male thread portion.

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