This application is based on Japanese Patent Application No. 2014-146280 filed on Jul. 16, 2014, the disclosure of which is incorporated herein by reference in its entirety.
The present disclosure relates to a valve timing controller.
A valve timing controller controls a rotation phase of a driven rotor that rotates with a camshaft relative to a driving rotor that rotates with a crankshaft using planet movement of a planet gear.
JP 4360426 B (US 2009/0017952 A1) describes a valve timing controller in which a driving side planet external gear part and a driven side planet external gear part of a planet gear mesh with a driving side solar internal gear part of a driving rotor and a driven side solar internal gear part of a driven rotor, respectively, in the eccentric state. The valve timing controller is suitably mounted to an internal combustion engine, for example, in a narrow space of a vehicle, since a large reduction ratio can be obtained with the downsized structure.
In JP 4360426 B, the planet gear and the driving rotor are supported by a planet bearing and a solar bearing respectively from an inner side in the radial direction, and a planet carrier is supported by the planet bearing and the solar bearing from an outer side in the radial direction. The planet gear can smoothly have planet movement according to a relative rotation of the planet carrier relative to the driving side solar internal gear part of the driving rotor, so it is possible to improve the control responsivity of the valve timing according to the rotation phase.
In JP 4360426 B, an elastic component is interposed between the planet carrier and the planet bearing, thereby biasing the planet gear to the eccentric side through the planet bearing relative to the driving rotor and the driven rotor. Thus, abnormal noise and wear are restricted at an engagement portion between the driving side solar internal gear part and the driving side planet external gear part and an engagement portion between the driven side solar internal gear part and the driven side planet external gear part.
In JP 4360426 B, the planet bearing has double rows of spherical rolling elements interposed between an outer wheel that supports the planet gear from a radially inner side and an inner wheel that supports the planet carrier from a radially outer side. Moreover, the solar bearing similarly has double rows of spherical rolling elements interposed between an outer wheel that supports the driving rotor from a radially inner side and an inner wheel that supports the planet carrier from a radially outer side.
It is an object of the present disclosure to provide a valve timing controller in which the durability is improved while the valve timing controller is downsized.
According to an aspect of the present disclosure, a valve timing controller that controls valve timing of a valve opened and closed by a camshaft by torque transferred from a crankshaft of an internal combustion engine includes a driving rotor, a driven rotor, a planet gear, a planet bearing, a solar bearing, a planet carrier, and an elastic component. The driving rotor rotates with the crankshaft, and has a driving side solar internal gear part. The driven rotor rotates with the camshaft, and has a driven side solar internal gear part that is located adjacent to the camshaft in an axial direction than the driving side solar internal gear part is. The planet gear is located on an eccentric side eccentric to the driving rotor and the driven rotor in a radial direction. The planet gear has a driving side planet external gear part meshing with the driving side solar internal gear part on the eccentric side, and a driven side planet external gear part meshing with the driven side solar internal gear part on the eccentric side at a location where the driven side planet external gear part is located adjacent to the camshaft than the driving side planet external gear part is. The driving side planet external gear part and the driven side planet external gear part of the planet gear integrally carry out planet movement to control a rotation phase of the driven rotor relative to the driving rotor. The planet bearing has a planet outer wheel that supports the planet gear from an inner side in the radial direction, a planet inner wheel located on an inner side of the planet outer wheel in the radial direction, and a single row of a plurality of planet spherical rolling elements between the planet outer wheel and the planet inner wheel. The solar bearing has a solar outer wheel that supports the driving rotor from an inner side in the radial direction, a solar inner wheel located on an inner side of the solar outer wheel in the radial direction, and a single row of a plurality of solar spherical rolling elements between the solar outer wheel and the solar inner wheel. The planet carrier is supported by the planet inner wheel and the solar inner wheel from an outer side in the radial direction and is rotated relative to the driving side solar internal gear part such that the planet gear carries out the planet movement. The elastic component is interposed between the planet inner wheel and the planet carrier to bias the planet gear to the eccentric side through the planet bearing and to bias the planet carrier on an opposite side opposite from the eccentric side. The planet gear is defined to have a definition cross-section perpendicular to the axial direction when the planet gear is located on the eccentric side in the radial direction relative to the driving rotor and the driven rotor. In the definition cross-section, the planet outer wheel has a planet side outer arc part that configures a raceway groove of the planet outer wheel on the eccentric side, the solar outer wheel has a solar side outer arc part that configures a raceway groove of the solar outer wheel on the opposite side opposite from the eccentric side, the planet inner wheel has a planet side inner arc part that configures a raceway groove of the planet inner wheel on the eccentric side, and the solar inner wheel has a solar side inner arc part that configures a raceway groove of the solar inner wheel on the opposite side opposite from the eccentric side. An imaginary straight line is defined by connecting a center of the planet side outer arc part and a center of the solar side outer arc part to each other. The planet side inner arc part and the solar side inner arc part are located on the imaginary straight line.
The elastic component interposed between the planet inner wheel and the planet carrier biases the planet gear to the eccentric side in the radial direction through the planet bearing, and biases the planet carrier to the opposite side opposite from the eccentric side. In the definition cross-section of the planet gear that is eccentric in the radial direction, the planet side inner arc part on the eccentric side and the solar side inner arc part on the opposite side are located on the imaginary straight line that connects the center of the planet side outer arc part on the eccentric side to the center of the solar side outer arc part on the opposite side.
Thus, in the planet bearing having the single row of rolling elements, the load caused by the elastic component concentrates on the interface where the planet spherical rolling element is in the rolling contact with the planet inner wheel at the eccentric side location or a location adjacent to the eccentric side location in the circumferential direction in the definition cross-section.
Similarly, in the solar bearing having the single row of rolling elements, the load caused by the elastic component concentrates at the contact part where the solar spherical rolling element is in the rolling contact with the solar inner wheel at the opposite side location or a location adjacent to the opposite side location in the circumferential direction in the definition cross-section.
Since the load is applied in the concentrated state along the imaginary straight line, the planet carrier can be supported in the stabilized state, and the contact surface pressure is limitedly generated at the location where the load is concentrated.
Therefore, the durability can be improved while the valve timing controller is downsized by adopting the planet bearing having the single row of rolling elements and the solar bearing having the single row of rolling elements.
Moreover, the planet side outer arc part and the solar side outer arc part are located on the imaginary straight line together with the planet side inner arc part and the solar side inner arc part.
Accordingly, in the planet bearing having the single row of rolling elements, the load caused by the elastic component concentrates on the interface where the planet spherical rolling element is in the rolling contact with each of the planet inner wheel and the planet outer wheel at the eccentric side location or a location adjacent to the eccentric side location in the circumferential direction in the definition cross-section.
Similarly, in the solar bearing having the single row of rolling elements, the load caused by the elastic component concentrates at the contact part where the solar spherical rolling elements is in the rolling contact with each of the solar inner wheel and the solar outer wheel at the opposite side location or a location adjacent to the opposite side location in the circumferential direction in the definition cross-section.
Since the load is applied in the concentrated state along the imaginary straight line, the planet carrier, the planet bearing and the solar bearing can be supported in the stabilized state, and the contact surface pressure is limitedly generated at the location where the load is concentrated. Accordingly, the durability can be further improved.
The above and other objects, features and advantages of the present disclosure will become more apparent from the following detailed description made with reference to the accompanying drawings. In the drawings:
Embodiments of the present disclosure will be described hereafter referring to drawings. In the embodiments, a part that corresponds to a matter described in a preceding embodiment may be assigned with the same reference numeral, and redundant explanation for the part may be omitted. When only a part of a configuration is described in an embodiment, another preceding embodiment may be applied to the other parts of the configuration. The parts may be combined even if it is not explicitly described that the parts can be combined. The embodiments may be partially combined even if it is not explicitly described that the embodiments can be combined, provided there is no harm in the combination.
An embodiment is described based on drawings.
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The actuator 4 shown in
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The driving rotor 10 is made of metal, and has a hollow structure. The driven rotor 20, the planet gear 30, the planet bearing 40, the planet carrier 50, and the elastic component 60 are arranged in the driving rotor 10. The driving rotor 10 has a sprocket component 13, a cover component 14 and a sun-gear component 11 interposed between the sprocket component 13 and the cover component 14. The sun-gear component 11 has a ring board shape. The sprocket component 13 has a based cylinder shape, and the cover component 14 has a stepped cylinder shape. The sun-gear component 11, the sprocket component 13 and the cover component 14 are tightened together.
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The driven rotor 20 has a driven side solar internal gear part 24 on the inner circumference surface of a peripheral wall part, and an addendum circle is located on the inner side of a root circle in the radial direction. The driven side solar internal gear part 24 is arranged between the driving side solar internal gear part 12 and the camshaft 2 in the axial direction, and is located at a position not overlapping with the driving side solar internal gear part 12 in the radial direction. The inside diameter of the driven side solar internal gear part 24 is set smaller than the inside diameter of the driving side solar internal gear part 12. The number of teeth of the driven side solar internal gear part 24 is set less than the number of teeth of the driving side solar internal gear part 12.
Hereafter, as shown in
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The driving side planet external gear part 32 meshes with the driving side solar internal gear part 12 on the eccentric side on which the planet gear 30 is eccentric to the rotors 10 and 20 (hereafter referred to “eccentric side” as shown in
As shown in
The planet outer wheel 42 has an outer raceway groove 43 that is a circular groove recessed outward in the radial direction and that continuously extends in the circumferential direction. The outer raceway groove 43 has an arc shape in the cross-section that is symmetrical in the axial direction.
The planet inner wheel 44 has an inner raceway groove 45 that is a circular groove recessed inward in the radial direction and that continuously extends in the circumferential direction. The inner raceway groove 45 has an arc shape in the cross-section that is symmetrical in the axial direction.
Each of the spherical rolling elements 46 is arranged between the outer raceway groove 43 and the inner raceway groove 45 in the rolling contact state relative to the perimeter surface. The raceway groove 43, 45 is in the rolling contact with the perimeter surface of the planet spherical rolling element 46.
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The solar inner wheel 74 is arranged on the inner side of the solar outer wheel 72 in the radial direction, and has an inner raceway groove 75 that is a circular groove recessed inward in the radial direction and that continuously extends in the circumferential direction. The inner raceway groove 75 has an arc shape in the cross-section that is symmetrical in the axial direction. The raceway groove 73, 75 is in the rolling contact with the perimeter surface of the solar spherical rolling element 76.
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The planet bearing part 54 is supported by the planet inner wheel 44 from the radially outer side, which is coaxially fitted onto the planet bearing part 54 through a minute clearance. Under this situation, the planet gear 30 supported by the planet carrier 50 through the planet bearing 40 is able to integrally have planet movement according to the relative rotation of the planet carrier 50 relative to the driving side solar internal gear part 12.
When the planet carrier 50 is rotated relative to the driving side solar internal gear part 12, the driving side planet external gear part 32 and the driven side planet external gear part 34 respectively meshing with the driving side solar internal gear part 12 and the driven side solar internal gear part 24 integrally have planet movement.
The planet movement means a movement in which the planet carrier 50 revolves (around the sun) in the revolving direction while the planet gear 30 rotates in the own circumferential direction.
The elastic component 60 made of metal is received in a recess portion 55 opened at two positions in the circumferential direction of the planet bearing part 54. Each elastic component 60 is a board spring having U-shaped cross-section. Each elastic component 60 is interposed between the inner circumference surface of the planet inner wheel 44 and the bottom surface of the recess portion 55 recessed inward in the radial direction of the planet bearing part 54 of the planet carrier 50, and is maintained in the compressed state, such that the elastic component 60 is elastically deformed.
As shown in
The total force of the restoring forces generated by the elastic components 60 acts on the planet inner wheel 44 toward the eccentric side. As a result, the elastic component 60 biases the planet gear 30 to the eccentric side through the planet bearing 40. Further, the total force of the restoring forces generated by the elastic components 60 acts on the planet carrier 50 toward the second side opposite from the eccentric side. Therefore, the elastic component 60 biases the planet carrier 50 to the second side.
The phase control unit 8 controls the rotation phase of the driven rotor 20 relative to the driving rotor 10 according to the rotation state of the control shaft 6, such that a suitable valve timing control is realized depending on the operational situation of the internal combustion engine.
Specifically, the control shaft 6 rotates with the same speed as the driving rotor 10. When the planet carrier 50 is not rotated relative to the driving side solar internal gear part 12, the external gear parts 32 and 34 of the planet gear 30 rotate with the rotors 10 and 20 without carrying out planet movement. As a result, the rotation phase is substantially not changed, and the valve timing is maintained.
When the control shaft 6 rotates with low speed or rotates in an opposite direction relative to the driving rotor 10, the planet carrier 50 rotates in the retard direction relative to the driving side solar internal gear part 12, and the driven rotor 20 rotates in the retard direction relative to the driving rotor 10, due to the planet movement of the external gear parts 32 and 34. As a result, the rotation phase is retarded, such that the valve timing is retarded.
When the control shaft 6 rotates with higher speed than the driving rotor 10, the planet carrier 50 rotates in the advance direction relative to the driving side solar internal gear part 12, and the driven rotor 20 is rotated in the advance direction relative to the driving rotor 10, due to the planet movement of the external gear parts 32 and 34. As a result, the rotation phase is advanced, such that the valve timing is advanced.
Details of the phase control unit 8 are explained.
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The planet outer wheel 42 and the planet inner wheel 44 are arranged offset from each other by a predetermined dimension δi in the axial direction, for example, by flash ground processing. The raceway grooves 43 and 45 are also offset from each other in the axial direction by substantially same dimension as the predetermined dimension δi.
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Furthermore, as shown in
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Under the above situation, in the definition cross-section S, the imaginary straight line L is defined to connect straightly the center Cpo of the planet side outer arc part 43po and the center Cso of the solar side outer arc part 73so to each other, as shown in
The advantages achieved in the present embodiment are explained below.
According to the present embodiment, the elastic component 60 interposed between the planet inner wheel 44 and the planet carrier 50 biases the planet carrier 50 away from the eccentric side, and biases the planet gear 30 to the eccentric side through the planet bearing 40. In the definition cross-section S along which the planet gear 30 is positioned eccentric in the radial direction, the planet side inner arc part 45pi on the eccentric side and the solar side inner arc part 75si on the opposite side opposite from the eccentric side are located on the imaginary straight line L connecting the center Cpo of the planet side outer arc part 43po on the eccentric side to the center Cso of the solar side outer arc part 73so on the opposite side.
Therefore, in the planet bearing 40 having the single row of rolling elements 46, the load caused by the elastic component 60 concentrates on the interface where the planet inner wheel 44 is in the rolling contact with the planet spherical rolling element 46, in the definition cross-section S, at the eccentric side location or a location adjacent to the eccentric side location in the circumferential direction. Further, in the solar bearing 70 having the single row of rolling elements 76, in the definition cross-section S, the load caused by the elastic component 60 concentrates at the location where the solar inner wheel 74 is in the rolling contact with the solar spherical rolling element 76, at the opposite side location or a location adjacent to the opposite side location in the circumferential direction.
Thus, the load is applied in the concentrated state along the imaginary straight line L, thereby stabilizing the posture of the planet carrier 50 and limiting the contact surface pressure to be generated at the position where the load is concentrated.
Therefore, in this embodiment, while the planet bearing 40 having the single row of rolling elements and the solar bearing 70 having the single row of rolling elements are adopted for downsizing, it is possible to improve the durability together with the downsizing, under the situation where devices attached to the internal combustion engine are further downsized in recent years.
In a comparison example, the posture of a planet carrier supported by the planet inner wheel and the solar inner wheel is unstable while adopting a single row type device to attain a downsizing. Concretely, in the comparison example, each of the solar inner wheel and the planet inner wheel is in the rolling contact with a spherical rolling element at plural places in the circumferential direction. Among the plural places, the load of an elastic component acts at much locations due to the posture change of a planet carrier. Since the contact surface pressure between the inner wheel and a spherical rolling element would increase at the much locations, the durability is lowered in the comparison example.
According to the present embodiment, the planet side outer arc part 43po and the solar side outer arc part 73so are located on the imaginary straight line L together with the planet side inner arc part 45pi and the solar side inner arc part 75si. Therefore, in the planet bearing 40 having the single row of rolling elements, the load of the elastic component 60 is concentratedly applied at the interface where the planet inner wheel 44 and the planet outer wheel 42 are in the rolling contact with the planet spherical rolling element 46, in the definition cross-section S, at the eccentric side location or a location adjacent to the eccentric side location in the circumferential direction.
Further, in the solar bearing 70 having the single row of rolling elements, the load of the elastic component 60 concentrates at the location where the solar inner wheel 74 and the solar outer wheel 72 are in the rolling contact with the solar spherical rolling element 76, in the definition cross-section S, at the opposite side location opposite from the eccentric side location or a location adjacent to the opposite side location in the circumferential direction.
Thus, the load is applied in the concentrated state on the imaginary straight line L, thereby stabilizing the posture of the planet carrier 50 and both the bearings 40 and 70, and limiting the contact surface pressure to be generated at the position where the load is concentrated. Therefore, the durability can be further raised.
Furthermore, according to the present embodiment, the planet outer wheel 42 is in the rolling contact with the planet spherical rolling element 46 at the location between the camshaft and the center Cpo of the planet side outer arc part 43po in the axial direction, and the planet inner wheel 44 is in the rolling contact with the planet spherical rolling element 46 at the location away from the camshaft through the center Cpo of the planet side outer arc part 43po. Therefore, it is easy to locate the arc parts 45pi and 43po on the imaginary straight line L in this embodiment.
Moreover, the solar outer wheel 72 is in the rolling contact with the solar spherical rolling element 76 at the location between the camshaft and the center Cso of the solar side outer arc part 73so in the axial direction, and the solar inner wheel 74 is in the rolling contact with the solar spherical rolling element 76 at the location away from the camshaft through the center Cso of the solar side outer arc part 73so. Therefore, it is easy to locate the arc parts 75si and 73so on the imaginary straight line L. Thus, the reliability of the effect improving the durability can be raised by surely stabilizing the orientations of the planet carrier 50 and both the bearings 40 and 70 and applying the load limitedly to the position where the load is concentrated.
Furthermore, according to the present embodiment, the planet outer wheel 42 is press-fitted to the planet gear 30 meshing with the internal gear part 12, 24 of the rotor 10, 20, such that the center Cpo of the planet side outer arc part 43po can be accurately positioned, which defines the raceway groove 43 of the planet outer wheel 42. The solar outer wheel 72 is press-fitted to the driving rotor 10 such that the center Cso of the solar side outer arc part 73so, which defines the raceway groove 73 of the solar outer wheel 72, can be positioned correctly.
Since each of the centers Cpo and Cso for assuming the imaginary straight line L is positioned in this way, the state where the inner arc parts 45pi and 75si are located on the imaginary straight line L and the state where the outer arc parts 43po and 73so are located on the imaginary straight line L can be maintained constantly. Thus, the reliability of the effect improving the durability can be raised by surely stabilizing the orientations of the planet carrier 50 and both the bearings 40 and 70 and applying the load limitedly to the position where the load is concentrated.
The planet gear 30 is supported by the thrust bearing part 26 of the driven rotor 20 from the camshaft side. Therefore, the planet gear 30 can be supported in the stabilized state. Accordingly, the planet carrier 50 can be supported in the stabilized state, while the planet bearing 40 is supported between the planet gear 30 and the planet carrier 50. Thus, the durability can be further improved while the inner arc part 45pi, 75si and the outer arc part 43po, 73so are located on the imaginary straight line L.
The above embodiment may be modified within a range not deviating from the scope of the present disclosure as defined by the appended claims.
In a first modification, as shown in
In a second modification, the rotors 10 and 20 may not have the thrust bearing part which supports the planet gear 30 from the camshaft side.
In a third modification, the planet outer wheel 42 coaxially fitted into the planet gear 30 with a minute clearance may support the planet gear 30 from the radially inner side.
In a fourth modification, the solar outer wheel 72 coaxially fitted into the cover component 14 with a minute clearance may support the driving rotor 10 from the radially inner side.
In a fifth modification, the planet inner wheel 44 to which the planet carrier 50 is coaxially press-fitted may support the planet carrier 50 from the radially outer side.
In a sixth modification, the solar inner wheel 74 to which the planet carrier 50 is coaxially press-fitted may support the planet carrier 50 from the radially outer side.
In a seventh modification, only the planet side inner arc part 45pi and the solar side inner arc part 75si are located on the imaginary straight line L, and the planet side outer arc part 43po and the solar side outer arc part 73so are not located on the imaginary straight line L.
Such changes and modifications are to be understood as being within the scope of the present disclosure as defined by the appended claims.
Number | Date | Country | Kind |
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2014-146280 | Jul 2014 | JP | national |
Number | Name | Date | Kind |
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8985075 | Tadokoro | Mar 2015 | B2 |
20090017952 | Sugiura et al. | Jan 2009 | A1 |
Number | Date | Country | |
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20160017771 A1 | Jan 2016 | US |