Patent Application
20130206087
The present invention relates to a valve timing control apparatus for an internal combustion engine, which variably controls opening and closing timings of an engine valve, i.e., an intake valve and/or an exhaust valve.
Recently, there has been proposed a valve timing control apparatus adapted to change a relative rotational phase between a crankshaft and a camshaft by transmitting a rotational force of an electric motor to the camshaft through a speed reducer and control opening and closing timings of an engine valve.
As well known, alternating torque is generated in the camshaft of the internal combustion engine due to a spring force of a valve spring that biases the engine valve in a closing direction of the engine valve.
For instance, Japanese Patent Application Unexamined Publication No. 2010-255543 discloses a valve timing control apparatus equipped with a speed reducer. The speed reducer includes an eccentric drive plate having a cylindrical eccentric cam on an inner peripheral side, a coupling plate, a follower plate, eccentric balls disposed between the eccentric drive plate and the coupling plate, and drive balls disposed between the eccentric drive plate and the follower plate. The eccentric balls are received in ball recesses respectively formed on the eccentric drive plate and the coupling plate. The drive balls are received in ball recesses respectively formed on the eccentric drive plate and the follower plate. By adjusting a clearance between the respective balls and the corresponding ball recesses, occurrence of noise can be suppressed even when the alternating torque generated in the camshaft is transmitted to the speed reducer.
Such adjustment of the clearance must be carried out under a condition that the eccentric cam is fitted onto an outer peripheral surface of a needle bearing disposed on an outer periphery of a cam bolt. In order to facilitate the adjustment of the clearance, a cylindrical output shaft of an electric motor and a large-diameter sleeve portion of the eccentric cam are formed separately from each other. After the adjustment of the clearance, the motor output shaft and the sleeve portion of the eccentric cam are coupled to each other to form an integral part by press-fitting in an axial direction thereof.
In the valve timing control apparatus of the above-described conventional art, in order to secure the cylindrical motor output shaft to the large-diameter sleeve portion of the eccentric cam, the motor output shaft and the large-diameter sleeve portion of the eccentric cam are integrally coupled to each other by press-fitting an inner peripheral surface of the motor output shaft onto an outer peripheral surface of the large-diameter sleeve portion. Therefore, it is necessary to increase an axial length of the motor output shaft and thereby ensure a sufficient press-fit tolerance. In such a case, when the motor output shaft is press-fitted onto the large-diameter sleeve portion, plastic deformation tends to be caused in the large-diameter sleeve portion (i.e., the eccentric cam). As a result, precision of the clearance between the respective balls and the ball recesses is deteriorated, thereby causing an unstable control condition of the valve timing control apparatus.
It is an object of the present invention to provide a valve timing control apparatus for an internal combustion engine in which the motor output shaft and the eccentric cam are integrally coupled to each other through a bearing and occurrence of plastic deformation in the eccentric cam is suppressed.
In one aspect of the present invention, there is provided a valve timing control apparatus for an internal combustion engine, the internal combustion engine including a crankshaft and a camshaft, the valve timing control apparatus including:
a drive rotation member to which a rotational force is transmitted from the crankshaft;
a follower rotation member fixed to the camshaft;
an electric motor including a rotor that is rotatable relative to the drive rotation member;
a speed reducer including a trochoid curve-shaped internal gear portion that is rotatable with the drive rotation member, a sleeve-shaped eccentric cam disposed on an inner peripheral side of the internal gear portion, the eccentric cam having an outer peripheral portion eccentric relative to a central axis thereof, a plurality of rollers disposed between the internal gear portion and the eccentric cam, and a comb-shaped cage that is rotatable with the follower rotation member, the cage supporting the plurality of rollers, the cage being rotated relative to the internal gear portion by rotation of the eccentric cam,
a tubular motor output shaft fixed to an inner periphery of the rotor, the motor output shaft being arranged in series relative to the eccentric cam in an axial direction thereof, and
a needle bearing that is rollable on a part of an outer peripheral surface of the follower rotation member,
wherein the eccentric cam and the motor output shaft are press-fitted onto an outer peripheral portion of the needle bearing, the needle bearing extending over both the eccentric cam and the motor output shaft in an axial direction thereof.
In a further aspect of the present invention, there is provided a valve timing control apparatus for an internal combustion engine, the internal combustion engine including a crankshaft and a camshaft, the valve timing control apparatus including:
a drive rotation member to which a rotational force is transmitted from the crankshaft;
a follower rotation member fixed to the camshaft;
an electric motor including a rotor that is rotatable relative to the drive rotation member;
a speed reducer including a trochoid curve-shaped internal gear portion that is rotatable with the drive rotation member, a ball bearing disposed on an inner peripheral side of the internal gear portion, the ball bearing including an outer race, an inner race having an outer peripheral surface eccentric relative to an inner peripheral surface thereof, a plurality of rollers disposed between the internal gear portion and the outer race of the ball bearing, and a comb-shaped cage that is rotatable with the follower rotation member, the cage supporting the plurality of rollers, the cage being rotated relative to the internal gear portion by rotation of the inner race of the ball bearing,
a tubular motor output shaft fixed to an inner periphery of the rotor, the motor output shaft having an axial end that abuts against the inner race of the ball bearing to thereby restrain an axial movement of the inner race of the ball bearing, and
a needle bearing that is rollable on a part of an outer peripheral surface of the follower rotation member,
wherein the inner race of the ball bearing and the motor output shaft are press-fitted onto an outer peripheral portion of the needle bearing, the needle bearing extending over both the inner race of the ball bearing and the motor output shaft in an axial direction thereof.
In a still further aspect of the present invention, there is provided a valve timing control apparatus for an internal combustion engine, the internal combustion engine including a crankshaft and a camshaft, the valve timing control apparatus including:
a drive rotation member to which a rotational force is transmitted from the crankshaft;
a follower rotation member fixed to the camshaft;
an electric motor including a rotor that is rotatable relative to the drive rotation member;
a speed reducer including at least one engagement portion, the one engagement portion being disposed in a transmission path through which a rotational force is transmitted from the electric motor, the speed reducer serving to reduce a rotational force transmitted from the rotor to an input portion and transmit the rotational force reduced to the follower rotation member,
a tubular motor output shaft fixed to the rotor;
a sleeve disposed such that an axial end portion thereof is opposed to an axial end portion of the motor output shaft, the sleeve being fixed to the input portion of the speed reducer, and
a bearing that is rollable on a part of an outer peripheral surface of the follower rotation member,
wherein the sleeve and the motor output shaft are press-fitted onto an outer peripheral portion of the bearing, the hearing extending over both the sleeve and the motor output shaft in an axial direction thereof.
According to the present invention, there is provided a valve timing control apparatus in which a motor output shaft and an eccentric cam are coupled to each other to form an integral part and occurrence of plastic deformation in the eccentric cam can be suppressed.
Other objects and features of this invention will become understood from the following description with reference to the accompanying drawings.
With reference to the accompanying drawings, first to fifth embodiments of a valve timing control apparatus for an internal combustion engine according to the present invention are explained. In the respective embodiments, the valve timing control apparatus is applied to a valve operating device for an intake valve, but the valve timing control apparatus can also be applied to a valve operating device for an exhaust valve.
As shown in
Timing sprocket 1 includes ring-shaped sprocket body 1a made of an iron-based metal material and formed with a stepwise inner peripheral surface. Gear wheel 1b is integrally formed with an outer periphery of sprocket body 1a and receives the rotational force from the engine crankshaft through a timing chain, not shown. Annular member 19 is disposed on a front end side of sprocket body 1a and integrally formed with sprocket body 1a.
Large-diameter ball bearing 43 is disposed between sprocket body 1a and follower member (i.e., follower rotation member) 9 disposed on a front end portion of camshaft 2. Timing sprocket 1 and camshaft 2 are relatively rotatably supported through large-diameter ball bearing 43.
As shown in
Sprocket body 1a has on an inner periphery thereof outer race fixing portion 60 that is opened toward a side of camshaft 2 and formed as an annular cutout.
As shown in
As shown in
Annular retaining plate 61 is disposed on a rear end portion of sprocket body 1a which is located on a side opposite to annular member 19. Retaining plate 61 is formed from a relatively thin metal sheet, and has an outer diameter substantially the same as that of sprocket body 1a and an inner diameter smaller than that of inner race 43b of large-diameter ball bearing 43.
Inner peripheral portion 61a of retaining plate 61 is opposed to outer end surface (i.e., the other axial end surface) 43e of outer race 43a with a given clearance therebetween so as to cover outer end surface 43e. Stop 61b is disposed in a predetermined position on an inner peripheral edge of inner peripheral portion 61a, and integrally formed with inner peripheral portion 61a. Stop 61b projects in a radially inward direction of retaining plate 61, that is, toward a central axis of retaining plate 61.
As shown in
Further, sprocket body 1a (i.e., annular member 19) has six bolt insertion holes lc on an outer peripheral portion thereof. Bolt insertion holes lc are formed at equal intervals in a circumferential direction of sprocket body 1a, and extend through sprocket body 1a. Female thread portion 6 of annular member 19 has six female threaded hole 6a in positions corresponding to respective bolt insertion holes 1c, 61d. Six bolts 7 are inserted into these holes 1c, 61d, 6a, thereby securing retaining plate 61, timing sprocket 1 and female thread portion 6 (i.e., housing 5) to each other.
Sprocket body 1a and annular member 19 constitute a casing of speed reducing mechanism 8 as explained later, and the casing and housing 5 constitute a housing unit.
Sprocket body 1a, annular member 19, retaining plate 61 and female thread portion 6 have substantially the same outer diameter.
Cover 3 is made of aluminum alloy and formed into a cup shape. Cover 3 has swelled portion 3a on a front end portion thereof which is formed so as to cover a front end portion of housing 5. Cylindrical wall 3b is formed on an outer peripheral side of swelled portion 3a, and extends along an axial direction of cover 3. As shown in
Further, as shown in
As shown in
Housing 5 includes housing body 5a and sealing plate 11 that seals a front end opening of housing body 5a. Housing body 5a is made of an iron-based metal material and formed into a closed-ended cylindrical shape by pressing. Sealing plate 11 is made of a non-magnetic synthetic resin material.
Housing body 5a has disk-shaped partition wall 5b on the side of a rear end thereof, and an annular fixing groove on an inner peripheral surface of a front end portion thereof. Sealing plate 11 is fitted into the fixing groove and fixed thereto.
As shown in
Camshaft 2 has two drive cams on an outer peripheral surface thereof which are provided each cylinder and operative to open intake valves, not shown. Further, camshaft 2 has flange portion 2a on a front end portion thereof which is integrally formed with camshaft 2.
As shown in
As shown in
Stop 61b is located closer to the side of camshaft 2 in an axial direction of retaining plate 61 than a part of retaining plate 61 which is fixed to sprocket 1a in an axially opposed relation to rear end surface 43e of outer race 43a. Stop 61b is out of contact with fixed end portion 9a of follower member 9, thereby suppressing interference between stop 61b and fixed end portion 9a.
Stop 61b and stop engaging groove portion 2b constitute a stop mechanism.
As shown in
Follower member 9 is integrally formed of an iron-based metal material. As shown in
Fixed end portion 9a is disposed in contact with front end surface 2e of flange portion 2a. Fixed end portion 9a is press-contacted with flange portion 2a and fixed thereto in the axial direction by an axial force of cam bolt 10.
As shown in
As shown in
Disposed between the outer periphery of fixed end portion 9a and the bottom wall of cage 41 is inner race fixing portion 63 to which inner race 43b of large-diameter ball bearing 43 is press-fitted and fixed.
As shown in
Rotational phase adjusting mechanism 4 includes electric motor 12 as an actuator which is disposed coaxially with camshaft 2 on a front side of timing sprocket 1, and speed reducer 8 that serves to reduce rotational speed of electric motor 12 and transmit the reduced rotational speed to camshaft 2.
Electric motor 12 is a brush-equipped DC motor. As shown in
As shown in
On the other hand, ring member 20 is press-fitted to an outer periphery of small-diameter portion 13b and fixed thereto. Commutator 21 is press-fitted to an outer peripheral surface of ring member 20 as explained later.
Ring member 20 has an outer diameter larger than that of large-diameter portion 13a, and an axial length slightly smaller than that of small-diameter portion 13b. Ring member 20 and commutator 21 constitute a commutator unit.
Core rotor 17 is made of a magnetic material having a plurality magnetic poles. Core rotor 17 has on an outer peripheral portion thereof a bobbin portion having slots in which coil windings 18a, 18b of electromagnetic coil 18 are disposed. As shown in
First jaw 17a and second jaw 17b serve to carry out positioning of coil windings 18a, 18b of electromagnetic coil 18 on an inner peripheral side of core rotor 17 closer to motor shaft 13. First jaw 17a on the side of commutator 21 is located slightly offset from second jaw 17b in a radially inward direction of core rotor 17. That is, first jaw 17a is disposed closer to large-diameter portion 13a of motor shaft 13, and a front end portion of first jaw 17a is overlapped with a part of commutator 21 in the radial direction of core rotor 17 such that annular space S is generated therebetween as shown in
Accordingly, electromagnetic coil 18 is wound such that coil winding 18a on the side of commutator 21 and coil winding 18b on the side of camshaft 2 are asymmetrically disposed with respect to core rotor 17 when viewed in cross-section taken along a rotation axis of motor shaft 13.
Specifically, coil winding 18a is arranged in a position close to motor shaft 13 through first jaw 17a. On the other hand, coil winding 18b is arranged close to partition wall 5b of housing 5 in such a state that coil winding 18b is accommodated in annular concave portion 5d of partition wall 5b through second jaw 17b. With this arrangement, it is possible to reduce an axial length of the valve timing control apparatus.
Commutator 21 is made of an electrically conductive material and formed into an annular shape. Commutator 21 is constituted of a plurality of segments. The number of the segments is the same as that of the magnetic poles of core rotor 17. Terminals drawn from electromagnetic coil 18 are electrically connected to the segments, respectively. That is, folded portion 21a is formed on the inner peripheral side of first jaw 17a, and serves as a connection portion in which a tip end of the respective terminals of electromagnetic coil 18 drawn through annular space S is pinched therein to allow electrical connection between electromagnetic coil 18 and commutator 21.
Permanent magnet pieces 14, 15 cooperate with each other to form a cylindrical shape, and have a plurality of magnetic poles in a circumferential direction thereof. Permanent magnet pieces 14, 15 are located in a position forwardly offset from core rotor 17 in an axial direction thereof.
Specifically, as shown in
As shown in
Slip rings 26a, 26b and second brushes 30a, 30b constitute a power supply mechanism. First brushes 25a, 25b, commutator 21, and pigtail harnesses 27a, 27b constitute a current-supply changeover mechanism.
As shown in
Brush retainer 28 serving as a power supplying brush unit is fixed to swelled portion 3a of cover 3. Brush retainer 28 is integrally molded from a synthetic resin material.
As shown in
Terminals 31, 31 are formed into a crank shape vertically extending in parallel to each other. Each of terminals 31, 31 has one end portion (i.e., a lower end portion) exposed to the side of a bottom of brush retaining portion 28a, and the other end portion (i.e., an upper end portion) 31b projecting into female engaging groove 28d.
Brush retaining portion 28a extends in a substantially horizontal direction (i.e. in an axial direction thereof). Brush retaining portion 28a includes sleeve-shaped slide portions 29a, 29b fixed into cylindrical through-holes that substantially horizontally extend in upper and lower positions in brush retaining portion 28a. Slide portions 29a, 29b respectively retain second brushes 30a, 30b so as to be slidable in an axial direction of the cylindrical holes.
Each of second brushes 30a, 30b has a generally rectangular prism shape. Second brushes 30a, 30b are respectively biased toward slip rings 26a, 26b in an axial direction thereof by second coil springs 32a, 32b such that rear end surfaces of second brushes 30a, 30b are respectively contacted with respective slip rings 26a, 26b. Each of second coil springs 32a, 32b is installed between a front end surface of each of second brushes 30a, 30b and the one end portion (not shown) of each of terminals 31, 31 exposed to a bottom of each of the cylindrical through-holes.
A rear end portion of each of second brushes 30a, 30b and the one end portion of each of terminals 31, 31 are electrically connected with each other through a resilient pigtail harness (not shown) welded thereto. The pigtail harness has such a predetermined length that each of second brushes 30a, 30b can be prevented from falling off from each of slide portions 29a, 29b when being urged to advance to a maximum slide position by each of coil springs 32a, 32b.
Further, annular seal member 34 is fitted into an annular engaging groove formed on an inner periphery of cylindrical wall 3b of cover 3. When brush retaining portion 28a is inserted into retaining hole 3c of cover 3, seal member 34 is elastically pressed onto an outer peripheral surface of a base portion of brush retaining portion 28a and seals an inside of brush retaining portion 28a.
The other end portion 31b of each of terminals 31, 31 is exposed to engaging groove 28d of connector portion 28b, and electrically connected to a control unit (not shown) through a male terminal (not shown) which is to be inserted into engaging groove 28d.
As shown in
Small-diameter ball bearing 37 is of a generally known type. Small-diameter ball bearing 37 includes inner race 37a, outer race 37b and a plurality of balls 37c disposed between inner race 37a and outer race 37b. Inner race 37a is fixedly disposed between front end surface 9e of cylindrical portion 9b of follower member 9 and seat surface 10d located on the rear side of head portion 10a of cam bolt 10. On the other hand, outer race 37b is held on an inner peripheral surface of large-diameter portion 13a of motor shaft 13 with a slight press-fit. One axial end surface (i.e., a front end surface) of outer race 37b is held in contact with inner peripheral step surface 13d of step portion 13c of motor shaft 13. Cylindrical spacer 54 is disposed between the outer peripheral surface of shaft portion 10b on the side of head portion 10a of cam bolt 10 and an inner peripheral surface of inner race 37a, and between the outer peripheral surface of shaft portion 10b and a recessed inner peripheral surface of a front end portion of cylindrical portion 9b of follower member 9.
Needle bearing 38 includes cylindrical retainer 38a made of iron-based metal, and a plurality of needle rollers 38b rotatably supported in retainer 38a.
Retainer 38a has both axial end portions bent in a radially inward direction of retainer 38a. Tip end portion (i.e., a rear end portion) 13e of large-diameter portion 13a of motor shaft 13 is press-fitted onto the side of one axial end (i.e., a front end) of an outer peripheral surface of retainer 38a. Eccentric cam 39 is press-fitted onto the side of the other axial end (i.e., a rear end) of the outer peripheral surface of retainer 38a. Respective needle rollers 38b roll on the outer peripheral surface of cylindrical portion 9b of follower member 9.
Small-diameter oil seal 46 is disposed between an outer peripheral surface of large-diameter portion 13a of motor shaft 13 and an inner peripheral surface of cylindrical wall portion 5f of partition wall 5b (i.e., an inner peripheral surface defining shaft insertion hole 5c). Small-diameter oil seal 46 separates speed reducer 8 and electric motor 12 from each other, and serves to prevent lubricating oil from leaking from an inside of speed reducer 8 into electric motor 12. An inner periphery of small-diameter oil seal 46 is elastically contacted with the outer peripheral surface of large-diameter portion 13a, thereby applying friction resistance to motor shaft 13 during rotation of motor shaft 13.
The control unit is configured to determine an operating condition of the engine on the basis of an information signal outputted from various sensors (not shown) such as a crank angle sensor, an air flow meter, an engine coolant temperature sensor, an accelerator position sensor, etc., and control the engine. The control unit is also configured to control rotation of motor shaft 13 by energizing electromagnetic coil 18 and control a rotational phase of camshaft 2 relative to timing sprocket 1 through speed reducer 8.
As shown in
As shown in
A As shown in
Metal washer 55 having a small thickness is fixedly disposed between front end portion 39a of eccentric cam 39 and a rear end surface of large-diameter portion 13a of motor shaft 13. Washer 55 is formed to have an inner diameter slightly larger than an outer diameter of needle bearing 38, and held on the outer peripheral surface of retainer 38a with a slight press-fit. Washer 55 is also formed to have an outer diameter slightly larger than an inner diameter of inner race 47a of intermediate-diameter ball bearing 47.
A plurality of through-holes 58 are formed in a position in fixed end portion 9a of follower member 9 in which fixed end portion 9a is opposed to eccentric cam 39 in the axial direction thereof. Through-holes 58 are arranged at substantially equal intervals therebetween in a circumferential direction of follower member 9. Through-holes 58 receive a given tool for restricting an amount of press-fit when eccentric cam 39 is press-fitted onto needle bearing 38 from the side of motor shaft 13.
Intermediate-diameter ball bearing 47 is disposed in a position where intermediate-diameter ball bearing 47 as a whole is substantially overlapped with needle bearing 38 in a radial direction thereof. Intermediate-diameter ball bearing 47 includes inner race 47a, outer race 47b and balls 47c disposed between inner and outer races 47a, 47b. Inner race 47a is press-fitted onto the outer peripheral surface of eccentric cam 39. Inner race 47a is sandwiched between washer 55 and snap ring 56 fitted onto an outer periphery of a rear end portion of eccentric cam 39. Thus, inner race 47a is held in a fixed state in an axial direction thereof by washer 55 and snap ring 56.
On the other hand, outer race 47b is held free without being restrained in an axial direction thereof. That is, one axial end surface of outer race 47b on the side of electric motor 12 is out of contact with any other component, and the other axial end surface thereof is opposed to the bottom wall of cage 41 with a slight first clearance C therebetween as shown in
As intermediate-diameter ball bearing 47 is eccentrically moved, respective rollers 48 are moved in a radial direction thereof and brought into engagement with internal gear portion 19a of annular member 19. Respective rollers 48 are also guided by both side edges of respective roller retaining holes 41b and swingably moved in the radial direction thereof.
Speed reducer 8 is supplied with lubricating oil through a lubricating oil supply path. As shown in
With the provision of the lubricating oil supply path, the lubricating oil is supplied to and stored in clearance 44 between side wall 41a of cage 41 and partition wall 5b of housing body 5a, and then supplied to moveable parts such as intermediate-diameter ball bearing 47 and respective rollers 48. The lubricating oil stored in clearance 44 is prevented from leaking into housing 5 by small-diameter oil seal 46.
Further, as shown in
An operation of valve time control apparatus 100 according to this embodiment will be explained hereinafter. When the crankshaft of the engine is rotationally driven to rotate timing sprocket 1 through the timing chain, the rotation force is transmitted to housing 5 through annular member 19 and female screw portion 6, thereby causing synchronous rotation of electric motor 12. On the other hand, the rotation force of annular member 19 is transmitted to camshaft 2 through respective rollers 48, cage 41 and follower member 9 so that the cam of camshaft 2 actuates the intake valve to be opened and closed.
When the engine is operated under a predetermined operating condition after the engine is started, the control unit outputs an exciting current to electromagnetic coil 18 of electric motor 12 through terminals 31, 31, the pigtail harnesses, second brushes 30a, 30b and slip rings 26a, 26b. Motor shaft 13 is rotationally driven so that the rotation force is inputted to speed reducer 8, and then the rotation force reduced is transmitted to camshaft 2.
Specifically, when eccentric cam 39 is rotated with the rotation of motor shaft 13, respective rollers 48 roll on internal gear portion 19a of annular member 19 so as to move from one of the teeth of internal gear portion 19a to the adjacent one of the teeth of internal gear portion 19a with rolling contact therewith, while being guided in roller retaining holes 41b of cage 41 in the radial direction of cage 41 per rotation of motor shaft 13. Respective rollers 48 move in the circumferential direction of cage 41 while repeating such rolling movement. Owing to the rolling movement of rollers 48, the rotation of motor shaft 13 is reduced, and the reduced rotation is transmitted to follower member 9. A speed reduction ratio at this time can be optionally set on the basis of the number of rollers 48.
As a result, camshaft 2 is rotated relative to timing sprocket 1 in a reverse direction to that of timing sprocket 1. Thus, a rotational phase of camshaft 2 relative to timing sprocket 1 is changed to thereby control the opening timing and the closing timing of the intake valve to a phase-advance side or a phase-retard side.
Camshaft 2 is controlled to the maximum rotational position (i.e., the maximum rotational phase position) relative to timing sprocket 1 by abutment of the side surfaces of stop 61b of retaining plate 61 against one of opposed surfaces 2c, 2d of stop engaging groove portion 2b of flange portion 2a of camshaft 2.
Specifically, when follower member 9 is rotated in the same direction as that of timing sprocket 1 in accordance with the rotation of eccentric cam 39, one side surface of stop 61h abuts against one surface 2c of stop engaging groove portion 2b to thereby restrain further rotation of camshaft 2 in the same direction. Accordingly, camshaft 2 is held in the maximum phase-advance position relative to timing sprocket 1.
On the other hand, when follower member 9 is rotated in a reverse direction to that of timing sprocket 1, the other side surface of stop 61b abuts against the other surface 2d of stop engaging groove portion 2b to thereby restrain further rotation of camshaft 2 in the reverse direction. Accordingly, camshaft 2 is held in the maximum phase-retard position relative to timing sprocket 1.
As a result, the opening timing and the closing timing of the intake valve is changed to the maximum phase-advance side or the maximum phase-retard side, so that fuel economy and output of the engine can be enhanced.
Further, in this embodiment, a coil of one coil winding 18a of electromagnetic coil 18 can be wound on first jaw 17a from the inner peripheral side sufficiently close to commutator 21. Therefore, even if the number of turns of the coil of coil winding 18a is increased, an amount of coil winding 18a projecting in the axial direction can be reduced. Further, the other coil winding 18b of electromagnetic coil 18 can be accommodated in annular concave portion 5d of partition wall 5b. With this arrangement, even if the number of turns of a coil of coil winding 18b is increased, an increased amount of coil winding 18b can be received in annular concave portion 5d. As a result, it is possible to reduce an axial length of valve timing control apparatus 100 as small as possible.
Further, in this embodiment, small-diameter oil seal 46 is arranged between the outer peripheral surface of large-diameter portion 13a of motor shaft 13 and the inner peripheral surface of cylindrical wall portion 5f of partition wall 5b. Since small-diameter oil seal 46 is effectively arranged in view of axial layout, the axial length of valve timing control apparatus 100 can be reduced to thereby enhance the installability relative to the engine.
Further, in this embodiment, motor shaft 13 and eccentric cam 39 are arranged separate from each other in the axial direction, and coupled with each other through needle bearing 38 by press-fitting the inner peripheral surfaces of motor shaft 13 and eccentric cam 39 onto the outer peripheral surface of retainer 38a of needle bearing 38 in the axial direction. With this construction, it is possible to suppress occurrence of plastic deformation in eccentric cam 39 upon press-fitting. In contrast, in the above-described conventional art, the motor shaft and the eccentric cam are directly coupled with each other to form an integral part by press-fitting in the axial direction which tends to have a risk of occurrence of plastic deformation.
That is, eccentric cam 39 is press-fitted not to motor shaft 13 but to needle bearing 38, so that an axial length of eccentric cam 39 can be reduced. Therefore, it is possible to reduce a press-fit tolerance of eccentric cam 39 relative to needle bearing 38, and therefore suppress occurrence of plastic deformation in eccentric cam 39 upon press-fitting.
With this construction, it is possible to reduce variation of the clearance generated at mutual contact or engagement portions between intermediate-diameter ball bearing 47, respective rollers 48 and internal gear portion 19a of annular member 19. As a result, a stable operation of speed reducer 8 can be obtained.
Further, this embodiment differs from the conventional art in that large-diameter portion 13a of motor shaft 13 is press-fitted to not both the outer periphery of eccentric cam 39 and the outer periphery of needle bearing 38, but only the outer periphery of needle bearing 38. With this construction, an outer diameter of large-diameter portion 13a can be sufficiently reduced to thereby increase the number of turns of the coil of coil winding 18 of core rotor 17 by an amount of reduction of the outer diameter of large-diameter portion 13a. As a result, it is possible to maintain the size of existing valve timing control apparatus 100 and enhance characteristics of electric motor 12 without increasing an entire axial length and an outer diameter of valve timing control apparatus 100
Further, in this embodiment, an outer diameter of motor shaft 13 can be reduced whereby an outer diameter of oil seal 46 disposed on the outer peripheral surface of large-diameter portion 13a of motor shaft 13 can be reduced. As a result, it is possible to reduce slide resistance that is caused between oil seal 46 and large-diameter portion 13a.
Further, in this embodiment, it is possible to readily manage press-fit of motor shaft 13 and eccentric cam 39 relative to needle bearing 38, and therefore, enhance the precision of the bearing and readily adjust the clearance generated at the mutual engagement portions of speed reducer 8. Further, in this embodiment, the assembling work can be simplified, and the production process can be facilitated, thereby serving for reducing the cost.
Further, in this embodiment, washer 55 is disposed between large-diameter portion 13a of motor shaft 13 and eccentric cam 39. Washer 55 cooperates with snap ring 56 to restrain axial movement of inner race 47a of intermediate-diameter ball bearing 47, so that the eccentric movement of eccentric cam 39 can be transmitted with high accuracy.
Further, in this embodiment, speed reducer 8 can be supplied with the lubricating oil through oil supply hole 51 and oil hole 52, so that lubrication characteristics of respective parts of speed reducer 8 can be enhanced. That is, since the lubricating oil is supplied between internal gear portion 19a and rollers 48, needle bearing 38, and intermediate-diameter ball bearing 47, the lubrication between needle rollers 38b and between balls 47c can be enhanced. Therefore, speed reducer 8 can always carry out smooth change of the rotational phase. In addition, the lubricating oil can attain a buffer function, thereby more effectively suppressing occurrence of a striking noise at the mutual contact or engagement parts of speed reducer 8.
In particular, during the operation of the engine, the lubricating oil fed from the oil pump is always supplied into clearance 44 between side wall 41a of cage 41 and partition wall 5b of housing body 5a through the lubricating oil supply path, so that clearance 44 is filled with the lubricating oil. Therefore, it is possible to suppress occurrence of lack of an oil film at the rolling members such as ball bearing 47 and the slide parts. As a result, an initial drive load of electric motor 12 can be sufficiently reduced, thereby serving for enhancing a response to control of the valve timing and reducing energy consumption.
Further, in this embodiment, speed reducer 8 and electric motor 12 can be integrally formed with each other through housing 5, and further integrally formed with timing sprocket 1 through sprocket body 1a. Therefore, these parts can constitute a one-piece unit, so that valve timing control apparatus 100 can be downsized in both the axial direction and the radial direction and can serve for ready management.
Further, in this embodiment, eccentric cam 39 is supported in such a state that eccentric cam 39 is sandwiched between needle rollers 38b of needle bearing 38 and balls 47c of ball bearing 47. With this construction, eccentric cam 39 can be stably supported.
Further, in this embodiment, it is possible to stably fix small-diameter ball bearing 37 and enhance axial positioning accuracy of motor output shaft 13 that abuts against outer race 37b of small-diameter ball bearing 37 in the axial direction.
Further, in this embodiment, with the provision of through-holes 58, when eccentric cam 39 is press-fitted onto needle bearing 38 from the side of motor shaft 13, a given tool for restricting an amount of press-fit of eccentric cam 39 can be introduced through through-holes 58.
Referring to
An inner peripheral side of tip end surface (i.e., rear end surface) 13f of large-diameter portion 13a is contacted with the front end surface of eccentric cam 39 in the axial direction. On the other hand, an outer peripheral side of tip end surface 13f is contacted with a front end surface of inner race 47a of intermediate-diameter ball bearing 47. Accordingly, tip end surface 13f of large-diameter portion 13a and snap ring 56 cooperate with each other to restrict axial movement of inner race 47a.
In the second embodiment, washer 55 can be omitted, thereby serving for reducing the number of parts and facilitating the production process and the assembling work.
Further, a relative position between motor shaft 13 and eccentric cam 39 in the axial direction can be determined in accordance with a contact portion between large-diameter portion 13a and eccentric cam 39.
Referring to
With the construction of needle bearing 38 having the larger outer diameter, it is possible to enhance rigidity of needle bearing 38 supporting motor shaft 13 and eccentric cam 39 and thereby increase strength of coupling between motor shaft 13 and eccentric cam 39.
Other construction of the third embodiment is the same as that of the first embodiment, and therefore, the third embodiment can attain substantially the same function and effect as those of the first embodiment.
Referring to
Referring to
In the fifth embodiment, inner race 47a is formed to have a radial thickness that gradually varies in the circumferential direction, and therefore, have an outer peripheral surface serving as a cam surface of eccentric cam 39 of the first to fourth embodiments.
Further, in the fifth embodiment, inner race 47a is press-fitted onto the outer peripheral surface of needle bearing 38. A front end surface of inner race 47a abuts against the tip end surface (i.e., the rear end surface) of large-diameter portion 13a of motor shaft 13 in the axial direction of inner race 47a, so that inner race 47a can be restrained from moving in the axial direction (i.e., in the forward direction).
With this construction, it is possible to omit eccentric cam 39 of the first embodiment and simplify the construction. As a result, the production process and the assembling work can be facilitated.
Furthermore, in the fifth embodiment, washer 55 and snap ring 56 as used in the first embodiment can be omitted to thereby facilitate the production process and the assembling work.
The present invention is not limited to the above embodiments, and may be variously modified. It is possible to use elements other than permanent magnet pieces 14, 15 of the above embodiments.
Further, various bearings, for instance, a plain bearing, a ball bearing having plural rows of balls, etc., other than needle bearing 38 can be used.
This application is based on a prior Japanese Patent Application No. 2012-30031 filed on Feb. 15, 2012. The entire contents of the Japanese Patent Application No. 2012-30031 are hereby incorporated by reference.
Although the invention has been described above by reference to certain embodiments of the invention and modifications of the embodiments, the invention is not limited to the embodiments and modifications described above. Further variations of the embodiments and modifications described above will occur to those skilled in the art in light of the above teachings. The scope of the invention is defined with reference to the following claims.
| Number | Date | Country | Kind |
|---|---|---|---|
| 2012-030031 | Feb 2012 | JP | national |
