This application is based on and incorporates herein by reference Japanese Patent Application No. 2014-141322 filed on Jul. 9, 2014.
The present disclosure relates to a valve timing control apparatus.
In a valve timing control apparatus of a hydraulic type, hydraulic oil is supplied into corresponding hydraulic chambers formed in a housing to rotate a vane rotor relative to the housing to adjust valve timing of intake valves and/or valve timing of exhaust valves of an internal combustion engine. In a case of a valve timing control apparatus disclosed in JPH09-280019A, hydraulic oil is supplied to the corresponding hydraulic chambers through an oil passage change valve that is placed in a center portion of a vane rotor. Furthermore, in the valve timing control apparatus disclosed in JPH09-280019A, a relatively large space is formed in a middle of a supply oil passage of a camshaft or a vane rotor to extend in an axial direction, and a mesh filter, which is configured into a cylindrical tubular form, is detachably installed in this space.
Inventors of the present application have an opinion of that in a case where a check valve is placed in the supply oil passage to limit a reduction in a response speed in a rotational phase control operation, the filter needs to be placed on an upstream side of the check valve in the supply oil passage in order to avoid malfunction of the check valve. This filter is a filter that can capture minute foreign objects that cannot be captured with a cartridge filter installed in the internal combustion engine. In this case, the placement of the filter in the location disclosed in JPH09-280019A is effective.
However, in the valve timing control apparatus of JPH09-280019A, the relatively large space, which extends in the axial direction, needs to be formed in the camshaft or the vane rotor to place the mesh filter, which is configured into the cylindrical tubular form, into the relatively large space. Thereby, an axial size of the valve timing control apparatus is disadvantageously increased, so that an installation space, which receives the valve timing control apparatus in the internal combustion engine, is disadvantageously increased in the axial direction.
The present disclosure is made in view of the above point. According to the present disclosure, there is provided a valve timing control apparatus that is placed in a drive force transmission path, which transmits a drive force from a drive shaft of an internal combustion engine to a driven shaft, to adjust valve timing of a valve that is opened and closed by the driven shaft. One of the drive shaft and the driven shaft serves as a first shaft while another one of the drive shaft and the driven shaft serves as a second shaft. An oil passage, which opens in an end surface of the second shaft, serves as an external oil passage. The valve timing control apparatus includes a housing, a vane rotor, an oil passage change valve, a check valve, a filter, and a filter holding body. The housing is rotatable together with the first shaft. The vane rotor is placed along an extension of an axis of the second shaft and is rotatable together with the second shaft. The vane rotor forms a vane, which partitions an inside space of the housing into an advancing chamber and a retarding chamber. The vane rotor includes an advancing oil passage, a retarding oil passage, and a supply oil passage. The advancing oil passage is communicated with the advancing chamber. The retarding oil passage is communicated with the retarding chamber. The supply oil passage opens on a side where the second shaft is placed. The supply oil passage is communicatable with the external oil passage. The oil passage change valve is placed in a center portion of the vane rotor and includes an advancing port, a retarding port and a supply port. The advancing port is communicated with the advancing oil passage. The retarding port is communicated with the retarding oil passage. The supply port is communicated with the supply oil passage. The oil passage change valve connects between the supply port and the advancing port at a time of rotating the vane rotor toward an advancing side relative to the housing and connects between the supply port and the retarding port at a time of rotating the vane rotor toward a retarding side relative to the housing. The check valve is provided between the second shaft and the vane rotor or is provided in an inside of the vane rotor. The check valve enables flow of hydraulic oil from the external oil passage to the supply oil passage and blocks flow of the hydraulic oil from the supply oil passage to the external oil passage. The filter is placed between the second shaft and the check valve and filters a foreign object contained in the hydraulic oil that flows from the external oil passage to the supply oil passage. The filter holding body is a laminated body, which is placed between the second shaft and the vane rotor and includes a plurality of metal plates that are stacked one after another in an axial direction of the vane rotor while the filter is clamped between corresponding two of the plurality of metal plates. The filter holding body includes a connection oil passage that connects between the external oil passage and the supply oil passage. The plurality of metal plates includes a first-side enlarged space forming plate and a second-side enlarged space forming plate. The first-side enlarged space forming plate is placed adjacent to the filter on one side of the filter where the second shaft is placed. The first-side enlarged space forming plate includes a first-side enlarged through hole, which forms a part of the connection oil passage, and a flow passage cross-sectional area of the first-side enlarged through hole is larger than a flow passage cross-sectional area of the supply oil passage. The second-side enlarged space forming plate is placed adjacent to the filter on another side of the filter where the vane rotor is placed. The second-side enlarged space forming plate includes a second-side enlarged through hole, which forms a part of the connection oil passage, and a flow passage cross-sectional area of the second-side enlarged through hole is larger than the flow passage cross-sectional area of the supply oil passage.
The drawings described herein are for illustration purposes only and are not intended to limit the scope of the present disclosure in any way.
Various embodiments of the present disclosure will be described with reference to the accompanying drawings. In the following discussion of the embodiments, similar components will be indicated by the same reference numerals and will not be described redundantly for the sake of simplicity.
First of all, an entire structure of the valve timing control apparatus 10 will be described with reference to
The housing 20 includes a sprocket 21, a front plate 25, and a rear plate 26. The sprocket 21 is placed along an extension of an axis of the camshaft 92 and is coaxial with the camshaft 92. The sprocket 21 forms a tubular portion 22, an external gear tooth portion 23 and a plurality of projecting portions 24. The external gear tooth portion 23, which has external gear teeth arranged one after another in a circumferential direction, is formed in an outer wall of the tubular portion 22 and is connected to the crankshaft 91 through a timing chain 93. The projecting portions 24 radially inwardly project from the tubular portion 22.
The front plate 25 is placed on one axial side of the sprocket 21. The rear plate 26 is placed on the other axial side of the sprocket 21, which is opposite from the one axial side. A fitting hole 27 is formed in a center part of the rear plate 26. The camshaft 92 is fitted into the fitting hole 27 of the rear plate 26. The sprocket 21, the front plate 25 and the rear plate 26 are secured together with bolts 28. The housing 20 is rotatable together with the crankshaft 91.
The vane rotor 30 is received in the housing 20 and is rotatable relative to the housing 20. The vane rotor 30 forms a boss 31 and a plurality of vanes 32. The boss 31 is fixed to the camshaft 92 with a sleeve bolt 41 described later. The vanes 32 radially outwardly project from the boss 31. Each of the vanes 32 partitions an inside space of the housing 20, that is, each of the vanes 32 partitions a space, which is circumferentially defined between corresponding adjacent two of the projecting portions 24, into an advancing chamber 33 and a retarding chamber 34. The retarding chamber 34 is located on one side of the vane 32 in a rotational direction, and the advancing chamber 33 is located on the other side of the vane 32 in the rotational direction.
The vane rotor 30 includes advancing oil passages 35, retarding oil passages 36, and supply oil passages 37. One end of each advancing oil passage 35 is communicated with the corresponding advancing chamber 33, and the other end of the advancing oil passage 35 opens in an inner wall surface of the boss 31. One end of each retarding oil passage 36 is communicated with the corresponding retarding chamber 34, and the other end of the retarding oil passage 36 opens in the inner wall surface of the boss 31. One end of each supply oil passage 37 opens in an end surface of the boss 31, which is located on a side where camshaft 92 is placed, and the other end of the supply oil passage 37 opens in the inner wall surface of the boss 31. An external oil passage 94 of the camshaft 92 is communicated with an oil pump 96 through an oil passage 95 formed in, for example, an engine block. The supply oil passages 37 are connected to the external oil passage 94.
The vane rotor 30 is rotated relative to the housing 20 when a pressure force of the hydraulic oil supplied to the advancing chambers 33 or the retarding chambers 34 is applied to the vane rotor 30 to change the rotational phase of the vane rotor 30 relative to the housing 20 to an advancing side or a retarding side.
The oil passage change valve 40 includes the sleeve bolt 41 and a spool 48.
The sleeve bolt 41 is inserted into a center portion of the vane rotor 30 from a side that is opposite from the camshaft 92 such that the sleeve bolt 41 is threaded into the camshaft 92. Furthermore, the sleeve bolt 41 forms a sleeve portion 44 between a head 42 and a threaded portion 43. The sleeve portion 44 is placed in an inside of the vane rotor 30. Furthermore, the sleeve portion 44 includes advancing ports 45, which are communicated with the advancing oil passages 35, retarding ports 46, which are communicated with the retarding oil passages 36, and supply ports 47, which are communicated with the supply oil passages 37.
The spool 48 is reciprocatable in the axial direction in an inside of the sleeve portion 44 of the sleeve bolt 41. The spool 48 can selectively communicate between corresponding ones of the ports of the sleeve portion 44 depending on an axial position of the spool 48. Specifically, in a case where the rotational phase of the vane rotor 30 relative to the housing 20 is changed to the advancing side, the spool 48 connects the supply ports 47 to the advancing ports 45 and communicates the retarding ports 46 to an external drain space located at an outside through the inside of the spool 48. Furthermore, in a case where the rotational phase of the vane rotor 30 relative to the housing 20 is changed to the retarding side, the spool 48 connects the supply ports 47 to the retarding ports 46 and communicates the advancing ports 45 to the external drain space through the outside of the spool 48.
A stopper plate 49 is fitted to an opening of the sleeve bolt 41, which is located in an inside of the head 42 of the sleeve bolt 41. The spool 48 is urged against the stopper plate 49 by a spring 39. An axial position of the spool 48 is determined by a balance between an urging force of the spring 39 and an urging force of a linear solenoid 97, which is located on an opposite side of the stopper plate 49 that is opposite from the spool 48.
In the valve timing control apparatus 10, which is constructed in the above-described manner, in the case where the rotational phase is on a retarding side of a target value, the oil passage change valve 40 connects each advancing chamber 33 to the supply oil passages 37 and also connects each retarding chamber 34 to the external drain space. In this way, the hydraulic oil is supplied to the advancing chambers 33, and the hydraulic oil is drained from the retarding chambers 34. Thereby, the vane rotor 30 is rotated relative to the housing 20 toward the advancing side.
Furthermore, in the case where the rotational phase is on the advancing side of the target value, the oil passage change valve 40 connects each retarding chamber 34 to the supply oil passages 37 and also connects each advancing chamber 33 to the external drain space. In this way, the hydraulic oil is supplied to the retarding chambers 34, and the hydraulic oil is drained from the advancing chambers 33 to the outside. Thereby, the vane rotor 30 is rotated relative to the housing 20 toward the retarding side.
Furthermore, in a case where the rotational phase coincides with the target value, the oil passage change valve 40 closes the advancing chambers 33 and the retarding chambers 34. In this way, the current rotational phase is maintained.
Next, a characteristic structure of the valve timing control apparatus 10 will be described with reference to
As shown in
The check valve 50 is placed between the camshaft 92 and the vane rotor 30 and is clamped between the vane rotor 30 and the filter holding body 60. In the present embodiment, as shown in
As shown in
The filter holding body 60 is placed between the camshaft 92 and the check valve 50 and includes a connection oil passage 66 that connects the external oil passage 94 to the supply oil passages 37. In the present embodiment, the filter holding body 60 is press fitted into a press fitting hole 38 of the vane rotor 30. The supply oil passages 37 open in a bottom surface of the press fitting hole 38. The check valve 50 is clamped and secured between the bottom surface of the press fitting hole 38 and the filter holding body 60.
Furthermore, the filter holding body 60 is a laminated body that includes a plurality of metal plates 61-65, which are stacked one after another in the axial direction of the vane rotor 30 while the filter 55 is clamped between corresponding two of the metal plates 61-65. Specifically, the filter holding body 60 includes a metal plate 61, two metal plates 62, the filter 55, a metal plate 62, three metal plates 63, a metal plate 64, and a metal plate 65, which are stacked one after another in this order from the camshaft 92 side.
Hereinafter, unless it is necessary to distinguish the respective metal plates 61-65, each of these metal plates 61-65 may be simply referred to as “metal plate”. Furthermore, a term “outer side” may refer to a radially outer side of the filter holding body 60 in a radial direction of the filter holding body 60, and a term “inner side” may refer to a radially inner side of the filter holding body 60 in the radial direction.
As shown in
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In the present embodiment, a thickness (a plate thickness) of each of the metal plates 61-65 is 0.4 mm, and a thickness (a plate thickness) of the filter 55 is 0.1 mm. An axial length of the filter holding body 60 including the filter 55 is 3.7 mm. The metal plates 61-65 and the filter 55 are stacked in the predetermined order discussed above and are press fitted into the press fitting hole 38 of the vane rotor 30. Rotational movement and axial movement of the metal plates 61-65 and the filter 55, which are press fitted into the press fitting hole 38 of the vane rotor 30, are limited by the knock pin 68, which is configured into a stepped form.
Now, advantages of the present embodiment will be described.
As discussed above, in the first embodiment, the valve timing control apparatus 10 includes the check valve 50, the filter 55, and the filter holding body 60. The check valve 50 is placed between the camshaft 92 and the vane rotor 30. The check valve 50 enables the flow of the hydraulic oil from the external oil passage 94 to the supply oil passages 37 and blocks the flow of the hydraulic oil from the supply oil passages 37 to the external oil passage 94. The filter 55 is placed between the camshaft 92 and the check valve 50.
The filter holding body 60 is the laminated body that is placed between the camshaft 92 and the check valve 50 and includes the metal plates 61-65 stacked in the axial direction of the vane rotor 30 while the filter 55 is clamped between the corresponding two of the metal plates 61-65, and the filter holding body 60 includes the connection oil passage 66, which connects between the external oil passage 94 and the supply oil passages 37. The three metal plates 62 serve as the enlarged space forming plates and form the corresponding part of the filter holding body 60. The two of the metal plates 62 are placed at the corresponding location, which is adjacent to the filter 55 on the one side of the filter 55 where the camshaft 92 is placed, and the remaining one of the metal plates 62 is placed at the corresponding location, which is adjacent to the filter 55 on the other side of the filter 55 where the vane rotor 30 is placed. Each of the metal plates 62 includes the enlarged through holes 73, which form the part of the connection oil passage 66 at the corresponding location that is adjacent to the filter 55. Furthermore, the flow passage cross-sectional area of each of the enlarged through holes 73 of each metal plate 62 is larger than the flow passage cross-sectional area of each supply oil passage 37 and is also larger than the flow passage cross-sectional area of the external oil passage 94.
With the above-described construction, the two metal plates 62, the filter 55 and the one metal plate 62 are sequentially placed one after another in the axial direction at the location between the external oil passage 94 and the supply oil passages 37. The enlarged through holes 73 of the two metal plates 62, which are placed on the upstream side of the filter 55, and the enlarged through holes 73 of the remaining one metal plate 62, which is placed on the downstream side of the filter 55, form the locally enlarged spaces (enlarged spaces) in the middle of the connection oil passage 66 to increase the total opening cross-sectional area of the filter 55 in the connection oil passage 66 for the purpose of reducing or minimizing the pressure loss at the filter 55. In order to increase the total opening cross-sectional area of the filter 55, the size of each of the enlarged through holes 73 may be increased. Therefore, even when the thickness of each metal plate 62 is small, the flow of the hydraulic oil is not interfered. Furthermore, the filter 55 is made of the sheet having the minute holes 75.
Therefore, the axial size of the valve timing control apparatus 10 can be reduced by shortening the axial distance between the camshaft 92 and the vane rotor 30. In this way, the installability of the valve timing control apparatus 10 on the internal combustion engine 90 can be improved.
Furthermore, in the first embodiment, the filter 55 is formed by the metal sheet.
Therefore, the filter 55 is made as one type of the plates of the laminated body that is formed along with the metal plates 61-65, and thereby the axial distance between the camshaft 92 and the vane rotor 30 can be reduced. Furthermore, the metal plates 61-65 and the filter 55 can be integrated together by the dimples 71, which are formed in the metal plates 61-65 and the filter 55 by, for example, a press working process.
Furthermore, in the first embodiment, the metal plates (identical metal plates, i.e., the common metal plates) 62 of the same type are used as the metal plates which form the enlarged spaces on the front side (the upstream side) and the rear side (the downstream side) of the filter 55 in the axial direction. The two metal plates 62 are placed on the one side of the filter 55 where the camshaft 92 is placed, and the one metal plate 62 is placed on the other side of the filter 55 where the vane rotor 30 is placed.
Therefore, the manufacturing costs can be reduced by the use of the common parts, and it is easy to make a difference between the axial size of the enlarged space on the upstream side of the filter 55 and the axial size of the enlarged space on the downstream side of the filter 55. The axial size of the enlarged space on the downstream side of the filter 55 is minimized to such an extent that the enlarged space does not interfere with the flow of the hydraulic oil. In contrast, in order to limit clogging of the filter 55 with the captured foreign objects, which are captured with the filter 55, the axial size of the enlarged space on the upstream side of the filter 55 is set to a sufficiently large size that is sufficient to receive the captured foreign objects therein.
Furthermore, in the first embodiment, the check valve 50 is the reed valve that has the valve elements 51, each of which is configured into a sheet form (plate form) and opens and closes the connection oil passage 66. The check valve 50 is clamped and secured between the filter holding body 60 and the vane rotor 30.
Therefore, the filter holding body 60 can have a function of a bushing that is required in a previously proposed apparatus in order to hold the check valve 50. Thus, in the present embodiment, a dedicated bushing is no longer required. Thereby, the number of the components can be reduced, and the assembling can be eased.
Furthermore, in the first embodiment, the metal plate 65, which serves as the valve seat forming plate and forms the part of the filter holding body 60, is adjacent to the check valve 50 on the one side of the check valve 50 where the camshaft 92 is placed. The metal plate 65 forms the valve seats 78, against which the valve elements 51 are seatable. The corresponding relief holes 79 open around each valve seat 78 to avoid or limit contact of the outer peripheral edge portion of the valve element 51 with the metal plate 65 when the valve element 51 is seated against the valve seat 78.
Therefore, it is possible to limit chipping (damaging) of the outer peripheral edge portion of each valve element 51 at the valve closing time of the check valve 50 (i.e., the time of seating the valve element 51 of the check valve 50 against the valve seat 78).
A valve timing control apparatus according to a second embodiment of the present disclosure will be described with reference to
As shown in
As shown in
As shown in
As discussed above, according to the second embodiment, the advantages, which are similar to the advantages of the first embodiment, can be achieved. Furthermore, since the check valve 81 is clamped and secured between the corresponding two of the metal plates of the filter holding body 80, the assembling can be eased.
In another embodiment of the present disclosure, an opening width of each minute hole 75 of each filter portion 74 of the filter 55 may be set to a value that is other than 0.2 mm, i.e., a value that is smaller than 0.2 mm or larger than 0.2 mm.
In another embodiment of the present disclosure, the respective metal plates of the filter holding body may be integrally assembled together by, for example, swaging (cold forging) or welding.
In another embodiment of the present disclosure, the filter may be formed by a plurality of metal sheets instead of the single metal plate.
In another embodiment of the present disclosure, the configuration of the metal plate(s), which is placed adjacent to the filter on the upstream side of the filter, may be different from the configuration of the metal plate, which is placed adjacent to the filter on the downstream side of the filter.
In another embodiment of the present disclosure, the valve timing control apparatus may be a valve timing control apparatus, which adjusts valve timing of exhaust valves of the internal combustion engine.
In another embodiment of the present disclosure, the number of the supply oil passages 37 may be changed from the two to one or larger than two. Also, the number of the through holes 77 of the metal plate 65 (and thereby the number of the through holes 77 of the metal plate 64 and the number of the valve elements 51 of the check valve 50, 81) may be changed from the two to one or larger than two.
The present disclosure is not limited the above embodiments. That is, the above embodiments may be further modified in various ways without departing from the principle of the present disclosure.
Number | Date | Country | Kind |
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2014-141322 | Jul 2014 | JP | national |
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Number | Date | Country |
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H9-280019 | Oct 1997 | JP |
2005-351182 | Dec 2005 | JP |
Number | Date | Country | |
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20160010516 A1 | Jan 2016 | US |