Valve timing adjusting apparatus

Information

  • Patent Grant
  • 6739298
  • Patent Number
    6,739,298
  • Date Filed
    Thursday, March 27, 2003
    21 years ago
  • Date Issued
    Tuesday, May 25, 2004
    20 years ago
Abstract
In a valve timing adjusting apparatus, rotating response speed of a vane rotor and a moving speed of a lock piston are changed according to changes of oil temperature and pressure. It sometimes happens that the lock piston passes the fitting hole before the lock piston is fitted in the fitting hole. Timing of actuating a solenoid valve is retard by a given delay time from timing of actuating a spool valve. The given delay time is decided by a map based on sensor signals representing the oil temperature and pressure input to ECU. The given delay time is shorter as the oil temperature increases and longer as the oil pressure increases.
Description




CROSS REFERENCE TO RELATED APPLICATIONS




This application is based upon and claims the benefit of priority of Japanese Patent Application No. 2002-88300 filed on Mar. 27, 2002, the content of which is incorporated herein by reference.




BACKGROUND OF THE INVENTION




1. Field of the Invention




The present invention relates to a valve timing adjusting apparatus that adjusts valve opening and closing timing (a valve timing) of at least one of an intake valve and an exhaust valve of an internal combustion engine (engine) and a method of controlling the same.




2. Description of Related Art




There is known a valve timing adjusting apparatus in which valve timing of at least one of an intake valve and an exhaust valve is adjusted by hydraulically controlling angular phase of a driven side rotating member rotatable together with a camshaft relative to a drive side rotating member receiving drive force from a crankshaft of an engine and rotatable together with the crankshaft, that is, controlling angular phase of the camshaft relative to the crankshaft to a given value.




According to a conventional vane type valve timing adjusting apparatus, a vane as the driven side rotating member is accommodated in the drive side rotating member in such a manner that angular phase of the vane relative to the drive side rotating member is variable and defined by controlling hydraulic pressure applied to the vane. Further, according to another conventional valve timing adjusting apparatus, a drive force transmitting member disposed between the drive side rotating member and the driven side rotating member is provided with a helical spline engagement mechanism and angular phase of the driven side rotating member relative to the drive side rotating member is varied by hydraulically moving reciprocatingly the drive force transmitting member.




In the valve timing adjusting apparatus mentioned above, it is preferable for a purpose of preventing engine cranking failure when the engine is cranked that the valve timing of at least one of the intake valve and the exhaust valve is kept at a middle between the most retard timing and the most advanced timing that is the most adequate timing for securing efficient engine cranking.




For example, in the valve timing adjusting apparatus in which a piston is provided in the driven side rotating member and a fitting hole, in which the piston can be fitted, is provided in the drive side rotating member, the angular phase of the driven side rotating member relative to the drive side rotating member is locked to the middle position between the most retard angular position and the most advanced angular position by inserting the piston into the fitting hole when the engine stops. Operation of fitting the piston in the fitting hole or operation of pulling the piston out of the fitting hole is controlled by force balance between biasing force of a spring urging the piston toward the fitting hole and hydraulic pressure acting on the piston in a direction in which the piston is pulled out of the fitting hole.




Further, in a certain engine condition, for example, in a case of rapidly reducing vehicle speed during a period when the vehicle is running at high and constant speed, it is preferable for preventing abnormal engine operation that the valve timing is held within a limited range between the most retard timing and the most advanced timing by controlling the angular phase of the driven side rotating member relative to the driven side rotating member to keep within an angular range corresponding to the limited range.




For example, in the valve timing adjusting apparatus in which the drive side rotating member is provided with an arc shaped restriction hole extending in a direction in which the driven side rotating member rotates relatively to the drive side rotating member and the driven side rotating member is provided with a piston that can be inserted into the restriction hole, the angular phase of the driven side rotating member relative to the drive side rotating member is controlled within an angular range defined with opposite ends of the arc shaped restriction hole by inserting the piston into the restriction hole.




However, rotating speed of the driven side rotating member relative to the drive side rotating member, speed of inserting the piston into the fitting hole and speed of pulling the piston out of the restriction hole are variable according to changes of pressure, temperature and the like of operating oil supplied from a hydraulic pressure supply source. Accordingly, in a structure in which the angular phase of the driven side rotating member relative to the drive side rotating member is locked to the middle angular position when the piston is inserted into the fitting, hole or in a structure in which the angular phase of the driven side rotating member relative to the drive side rotating member is restricted within the angular range defined by opposite ends of the arc shaped restriction hole when the piston is inserted into the restriction hole, it sometimes happens that the piston passes the fitting or restriction hole before the piston is inserted into the hole or the piston is unlikely pulled out of the hole since the drive side rotating member excessively rotates relatively to the drive side rotating member before the piston has been pulled out of the hole.




SUMMARY OF THE INVENTION




An object of the present invention is to provide a valve timing adjusting apparatus in which a lock piston can be fitted in or pulled out of a fitting hole without fail.




Another object of the present invention is to provide a valve timing adjusting apparatus in which a restriction piston can be inserted into or pulled out of a restriction hole without fail.




A further object of the present invention is to provide a method of controlling the valve timing adjusting apparatus.




To achieve the above object, a valve timing adjusting apparatus disposed between a drive shaft of an internal combustion engine and a driven shaft causing an opening and closing operation of at least one of an intake valve and an exhaust valve and operative to change an angular phase of the driven shaft relative to the drive shaft so that opening and closing timing of the at least one of an intake valve and an exhaust valve may be varied has drive and driven side rotating members, rotation control pressure chamber, a lock piston, a fitting hole and an angular phase locking pressure chamber.




The drive side rotating member is rotated together with the drive shaft. The driven side rotating member is rotated together with the driven shaft. The rotation control pressure chamber is operative to rotate the driven side rotating member relative to the drive side rotating member so that angular phase of the driven side rotating member relative to the drive side rotating member is controlled to a target position between the most retard angle position and the most advanced angle position in response to hydraulic pressure applied thereto. The lock piston is provided in one of the driven and drive side rotating members. The fitting hole is provided in the other of the driven and drive side rotating members. The angular phase locking pressure chamber is operative to execute one of first and second operations when hydraulic pressure is applied thereto and the other of the first and second operations when application of the hydraulic pressure thereto is released. The first operation is to insert the lock piston into the fitting hole so as to lock the angular phase of the driven side rotating member relative to the drive side rotating member to a middle position between the most retard angle position and the most advanced angle position, and the second operation is to pull the lock piston out of the fitting hole so as to release lock of the angular phase of the driven side rotating member relative to the drive side rotating member at the middle position.




With the valve timing adjusting apparatus mentioned above, a supply route of the hydraulic pressure to the rotation control pressure chamber is different from that to the angular phase locking pressure chamber and, when at least one of the first and second operations is executed, start timing of rotation of the driven side rotating member relative to the drive side rotating member so as to change the angular phase of the driven side rotating member relative to the drive side rotating member to the target position is retard by a given delay time from start timing of execution of the at least one of the first and second operations.




It is preferable that the lock piston is provided at an axial end thereof with a tapered portion whose diameter is smaller toward the round hole, the fitting hole is provided at an opening end thereof with a chamfering portion whose diameter is larger toward the piston, and, when the first operation is executed, the given delay time by which the start timing of rotation of the driven side rotating member relative to the drive side rotating member is retard from the start timing of execution of the first operation is larger than time required for the tapered portion to pass the chamfering portion after the first operation starts.




When the intake or exhaust valve is driven, the driven shaft receives fluctuating torque acting in retard or advanced angle direction. Since average of the fluctuating torque acts in a retard angle direction, the driven side rotating member receives the fluctuating torque which causes the angular phase of the driven side rotating member relative to the drive side rotating member to change in retard angle direction.




Accordingly, it is preferable that, after the second operation starts, the hydraulic pressure is applied to the rotation control pressure chamber in such a manner that the angular phase of the driven side rotating member relative to the drive side rotating member is kept at the middle position between the most retard angle position and the most advanced angle position or temporarily moved to a position slightly shifted from the middle position toward the advanced angle position before the given delay time lapses. Since the fluctuating torque acting on the driven side rotating member in retard angle direction is reduced, the lock piston can be pulled out of the fitting hole with less frictional resistance.




A rotation speed of the driven side rotating member relative to the drive side rotating member and a moving speed of the lock piston are variable according to change of pressure of the operation oil. Further, the rotation speed of the driven side rotating member relative to the drive side rotating member and the moving speed of the lock piston are also variable according to change of viscosity of the operation oil that is changed by temperature of the operation oil.




Accordingly, it is preferable that the given delay time by which the start timing of rotation of the driven side rotating member relative to the drive side rotating member is retard from the start timing of execution of the at least one of the first and second operations is determined by sensor signals representing pressure and temperature of fluid applied to at least one of the rotation control pressure chamber and the angular phase locking pressure chamber.




Preferably, the valve timing adjusting apparatus further has a restriction piston, a restriction hole and an angular phase restriction pressure chamber. The restriction piston is provided in one of the driven and drive side rotating members. The restriction hole is formed in shape of an arc extending within a given angular range and provided in the other of the driven and drive side rotating members. The angular phase restriction pressure chamber is operative to execute one of third and fourth operations when hydraulic pressure is applied thereto and the other of the third and fourth operations when application of the hydraulic pressure thereto is released. The third operation is to insert the restriction piston into the restriction hole so as to restrict rotation of the driven side rotating member relative to the drive side rotating member within the given angular range and the fourth operation is to pull the restriction piston out of the restriction hole so as to release restriction of rotation of the driven side rotating member relative to the drive side rotating member within the given angular range. With the construction mentioned above, a supply route of the hydraulic pressure to the angular phase restriction pressure chamber is same as that to the angular phase locking pressure chamber, an end of the given angular range is at a position corresponding to the middle position between the most retard angle position and the most advanced angle position and the other end of the given angular range is at a position away from the middle position toward the most advanced angle position and, when the third operation is executed together with the first operation, the restriction piston abuts on the end of the given angular range within the restriction hole.




As an alternative, a valve timing adjusting apparatus disposed between a drive shaft of an internal combustion engine and a driven shaft causing an opening and closing operation of at least one of an intake valve and an exhaust valve and operative to change an angular phase of the driven shaft relative to the drive shaft so that opening and closing timing of the at least one of an intake valve and an exhaust valve may be varied has drive and driven side rotating members, rotation control pressure chamber, a restriction piston, a restriction hole and an angular phase restriction pressure chamber.




The drive side rotating member is rotated together with the drive shaft. The driven side rotating member is rotated together with the driven shaft. The rotation control pressure chamber is operative to rotate the driven side rotating member relative to the drive side rotating member so that angular phase of the driven side rotating member relative to the drive side rotating member is controlled to a target position between the most retard angle position and the most advanced angle position in response to hydraulic pressure applied thereto. The restriction piston is provided in one of the driven and drive side rotating members. The restriction hole is provided in the other of the driven and drive side rotating members. The angular phase restriction pressure chamber is operative to execute one of first and second operations when hydraulic pressure is applied thereto and the other of the first and second operations when application of the hydraulic pressure thereto is released. The first operation is to insert the restriction piston into the restriction hole so as to restrict rotation of the driven side rotating member relative to the drive side rotating member within the given angular range and the fourth operation being to pull the restriction piston out of the restriction hole so as to release restriction of rotation of the driven side rotating member relative to the drive side rotating member within the given angular range.




With the valve timing adjusting apparatus mentioned above, a supply route of the hydraulic pressure to the rotation control pressure chamber is different from that to the angular phase restriction pressure chamber and, when at least one of the first and second operations is executed, start timing of rotation of the driven side rotating member relative to the drive side rotating member so as to change the angular phase of the driven side rotating member relative to the drive side rotating member to the target position is retard by a given delay time from start timing of execution of the at least one of the first and second operations.




When the first operation is executed, the hydraulic pressure is applied to the rotation control pressure chamber in such a manner that, if the restriction piston is outside the given angular range of the restriction hole, the angular phase of the driven side rotating member relative to the drive side rotating member is temporarily moved to a position slightly inside the given angular range of the restriction hole before the given delay time lapses, whereby, when the driven side rotating member is rotated relatively to the drive side rotating member after the given delay time lapses, the target position of the angular phase of the driven side rotating member relative to the drive side rotating member is restricted within the given angular range since the restriction piston abuts on the retard angle side end or the advanced angle side end.




Further, it is preferable that, after the second operation starts, the hydraulic pressure is applied to the rotation control pressure chamber in such a manner that, before the given delay time lapses, the angular phase of the driven side rotating member relative to the drive side rotating member is temporarily moved to a position slightly away inward from the retard angle side end or the advanced angle side end of the restriction hole on which the restriction piston abuts so as to pull smoothly the restriction piston out of the restriction hole.




Preferably, the given delay time by which the start timing of rotation of the driven side rotating member relative to the drive side rotating member is retard from the start timing of execution of the at least one of the first and second operations is determined by sensor signals representing pressure and temperature of fluid applied to at least one of the rotation control pressure chamber and the angular phase restriction pressure chamber.




The valve timing adjusting apparatus further has a lock piston, a fitting hole and an angular phase locking pressure chamber. The lock piston is provided in one of the driven and drive side rotating members. The fitting hole is provided in the other of the driven and drive side rotating members. The angular phase locking pressure chamber is operative to execute one of third and fourth operations when hydraulic pressure is applied thereto and the other of the third and fourth operations when application of the hydraulic pressure thereto is released. The third operation is to insert the lock piston into the fitting hole so as to lock the angular phase of the driven side rotating member relative to the drive side rotating member to a given position within the given angular range of the restriction hole and the second operation is to pull the lock piston out of the fitting hole so as to release lock of the angular phase of the driven side rotating member relative to the drive side rotating member at the given position.




With the construction mentioned above, a supply route of the hydraulic pressure to the angular phase locking pressure chamber is same as that to the rotation control pressure chamber.











BRIEF DESCRIPTION OF THE DRAWINGS




Other features and advantages of the present invention will be appreciated, as well as methods of operation and the function of the related parts, from a study of the following detailed description, the appended claims, and the drawings, all of which form a part of this application. In the drawings:





FIG. 1

is a cross sectional view of a valve timing adjusting apparatus according to a first embodiment of the present invention;





FIG. 2

is a cross sectional view taken along a line II—II in

FIG. 1

;





FIG. 3

is schematic cross sectional views of a lock piston and a fitting hole according to the first embodiment;





FIG. 4

is a schematic view showing oil passages according to the first embodiment;





FIG. 5

is a characteristic graph showing relationship between oil temperature and a response speed;





FIG. 6

is a characteristic graph showing relationship between oil temperature and a moving speed of the lock piston;





FIG. 7

is a characteristic graph showing a relationship between oil temperature and delay time;





FIG. 8

is a characteristic graph showing a relationship between oil pressure and delay time;





FIGS. 9A

,


9


B and


9


C are schematic views showing an operation of the lock piston to be inserted into the fitting hole according to the first embodiment;





FIG. 10

is a flow chart showing a control routine when the lock piston is fitted in the fitting hole according to the first embodiment;





FIGS. 11A

,


11


B and


11


C are schematic views showing an operation of the lock piston to be pulled out of the fitting hole according to the first embodiment;





FIG. 12

is a flow chart showing a control routine when the lock piston is pulled out of the fitting hole according to the first embodiment;





FIGS. 13A

,


13


B and


13


C are schematic views showing oil passages and operation of a restriction piston to be inserted into a restriction hole according to a second embodiment of the present invention;





FIG. 14

is a flow chart showing a control routine when the restriction piston is inserted into the restriction hole according to the second embodiment;





FIGS. 15A

,


15


B and


15


C are schematic views showing an operation of the restriction piston to be pulled out of the restriction hole according to a second embodiment; and





FIG. 16

is a flow chart showing a control routine when the restriction piston is pulled out of the restriction hole according to the second embodiment.











DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS




Embodiments of the present invention are described with reference to figures.




(First Embodiment)




As shown in

FIGS. 1 and 2

, a valve timing adjusting apparatus


1


is a hydraulic control device for adjusting a valve timing of an intake valve. The valve timing adjusting apparatus


1


is composed of a main body


2


, a camshaft


3


, a bearing


4


for the camshaft


3


, a spool valve


230


as a first electrically controlled valve and a solenoid valve


240


as a second electrically controlled valve.




As shown in

FIG. 1

, drive force of a crankshaft (not shown) constituting a drive shaft is transmitted through the main body


2


to the camshaft


3


constituting a driven shaft. A cam formed in the camshaft


3


drives the intake valve. The main body


2


has a housing


10


, vane rotor


15


, a lock piston


30


and a restriction piston


44


(refer to FIG.


4


). The housing


10


is a drive side rotating member and has a timing gear


11


constituting a side wall, a circumferential wall


12


and a front plate


13


constituting the other side wall. The timing gear


11


and the front plate


13


are in contact with opposite axial ends of the circumferential wall


12


, respectively. The timing gear


11


, the circumferential wall


12


and the front plate


13


are concentrically fixed to one another by bolts. The timing gear


11


is connected via gears (no shown) to the crankshaft for receiving drive force therefrom and rotating together with the crankshaft.




The camshaft


3


is held by the bearing


4


. The drive force of the crankshaft is transmitted via the housing


10


and the vane rotor


15


to the camshaft


3


for an opening and closing operation of the intake valve (not shown). The camshaft


3


is rotatable with the timing gear


11


with a given angular phase difference therebetween. The housing


10


and the camshaft


3


rotate clockwise when viewed in a direction of an arrow A in FIG.


1


. This clockwise direction is advanced angle direction.




As shown in

FIG. 2

, the circumferential wall


12


is provided at an inner circumference thereof with four shoes


12




a


,


12




b


,


12




c


and


12




d


, that is, partitions formed in trapezoidal shape, arranged circumferentially at generally regular intervals. Each of inner circumferential surfaces of the shoes


12




a


,


12




b


,


12




c


and


12




d


is formed in arc cross sectional shape. Four fan shaped accommodation chambers


50


are formed in circumferential spaces between adjacent two of the shoes


12




a


,


12




b


,


12




c


and


12




d


. Vanes


15




a


,


15




b


,


15




c


and


15




d


are accommodated in the accommodation chambers


50


, respectively, and movable circumferentially within a given angular range.




The vane rotor


15


has a boss


15




e


and the vanes


15




a


,


15




b


,


15




c


and


15




d


that are arranged around the boss


15




e


circumferentially at generally regular intervals. The vanes


15




a


,


15




b


,


15




c


and


15




d


are rotatably accommodated in the accommodation chambers


50


. Each of the accommodation chambers


50


is partitioned by each of the vanes into two rooms. One is a retard angle hydraulic chamber and the other one is an advanced angle hydraulic chamber. Arrows in

FIG. 2

represent retard and advanced angle directions when the vane rotor


15


rotates relatively to the housing


10


. The vane rotor


15


representing the driven side rotating member is in contact with an axial end of the camshaft


3


and fixed to the camshaft


3


by a bolt


21


.




A spring


25


is inserted between the front plate


13


and the vane rotor


15


. An end of the spring


25


is retained by the front plate


13


and the other end thereof is retained by the vane rotor


15


. The spring


25


urges the vane rotor


15


in the advanced angle direction relative to the front plate


13


.




The vane rotor


15


is rotatable relatively to the housing


10


. Inner surfaces of the housing


10


at opposite axial ends, that is, inner walls of the timing gear


11


and the front plate


13


, are in slidable contact with outer surfaces of the vane rotor


15


at the opposite axial ends, respectively. Inner circumference of the circumferential wall


12


is in slidable contact with an outer circumference of the vane rotor


15


.




As shown in

FIG. 1

, the lock piston


30


constituting a cylindrical locking member is accommodated to move axially and reciprocatingly in an accommodation hole


38


formed in the vane


15




a


. The timing gear


11


is provided with an arc shaped elongated hole


34


(refer to

FIGS. 3 and 4

) whose depth is deeper at an advanced angle end. A fitting ring


35


is press fitted to the elongated hole


34


at the advanced angle end and constitutes a fitting hole


36


. The lock piston


30


can be inserted into and fitted in the fitting hole


36


. The lock piston


30


is provided at an axial end thereof with a tapered portion


31


whose diameter is smaller toward the fitting hole


36


. The fitting hole


36


is provided at an opening end thereof with a chamfering portion


32


whose diameter is larger toward the lock piston


30


so that the lock piston


30


is smoothly inserted into the fitting hole


36


. When the lock piston


30


enters toward the fitting hole


36


by more than length L1 from an entrance of the fitting hole, as shown in

FIG. 3

, the lock piston


30


is fitted in the fitting hole


36


. When the lock piston


30


enters toward the fitting hole


36


or the elongated hole


34


by more than length L2 corresponding to a longer one of axial length of the tapered portion


31


and axial length of the chamfering portion


36


, as shown in

FIG. 3

, the lock piston


30


does not pass the fitting hole


36


or the elongated hole


34


. A spring


37


as biasing means for the locking member urges the lock piston


30


toward the fitting hole


36


.




Pressure of operation oil applied to piston chambers


40


and


41


, both of which are operative as lock releasing chambers, urges the lock piston


30


to be pulled out of the fitting hole


36


. The lock piston


30


, the fitting hole


36


, the spring


37


and the piston chambers


40


and


41


constitute angular phase locking means. The piston chambers


40


and


41


communicate with a piston oil passage


203


for releasing hydraulic pressure. The lock piston


30


can be inserted into the fitting hole


36


when an angular phase of the vane rotor


15


relative to the housing


10


is at a middle position between the most retard angle position and the most advanced angle position and, in a state that the lock piston


30


is fitted in the fitting hole


36


, rotation of the vane rotor


15


relative to the housing


10


is locked. The middle position at which the lock piston


30


is fitted in the fitting hole


36


is set to a valve timing of the intake valve suitable for engine cranking.




When the vane rotor


15


rotates relatively to the housing


10


toward the retard or advanced angle position beyond the middle position, the lock piston


30


can not be fitted in the fitting hole


36


since the piston


30


is not angularly aligned with the fitting hole


36


.




A communication passage


13




a


formed in the front plate


13


shown in

FIG. 1

communicates via an arc shaped communication hole


39


formed in the vane


15




a


with an accommodation hole


38


formed on an opposite side of the fitting hole


36


with respect to the lock piston


30


. The lock piston


30


can move reciprocatingly without receiving any resistance from the operation oil since the communication passage


13




a


is opened to atmosphere.




As shown in

FIG. 4

, a restriction piston


44


is accommodated in the vane


15




a


so as to move reciprocatingly in an axial direction of the vane


15




a


. An arc shaped restriction hole


45


is formed to extend within a given angular range in the front plate


13


. The restriction piston


44


can be inserted into the restriction hole


45


. A spring


46


as restriction biasing means urges the piston


44


toward the restriction hole


45


.




Pressure of operation oil applied to piston chambers


48


and


49


, both of which are operative as restriction releasing chambers, urges the restriction piston


44


to be pulled out of the restriction hole


45


. The restriction piston


44


, the restriction hole


45


, the spring


46


and the piston chambers


48


and


49


constitute angular phase restriction means. The piston chambers


48


and


49


communicate with the piston oil passage


203


similarly to the piston chambers


40


and


41


. The operation oil is supplied to the piston chambers


40


,


41


,


48


and


49


commonly from the same hydraulic pressure source via the same supply route so that moving start timings of the lock and restriction pistons


30


and


44


are generally same. A retard angle side end of the restriction hole


45


corresponds to the middle position where the lock piston


30


is fitted in the fitting hole


36


. Accordingly, the restriction piston


44


abuts on the retard angle side end of the restriction hole


45


in a state that the lock piston


30


is fitted in the fitting hole


36


.




As shown in

FIG. 2

, retard angle hydraulic pressure chambers


51


,


52


,


53


and


54


are formed between the shoe


12




a


and vane


15




a


, between the shoe


12




b


and the vane


15




b


, between the shoe


12




c


and the vane


15




c


and between the shoe


12




d


and the vane


15




d


, respectively. Advanced angle hydraulic chambers


55


,


56


,


57


and


58


are formed between the shoe


12




d


and vane


15




a


, between the shoe


12




a


and the vane


15




b


, between the shoe


12




b


and the vane


15




c


and between the shoe


12




c


and the vane


15




d


, respectively.




As shown in

FIG. 1

, the camshaft


3


is provided on an outer circumferential wall thereof that slides on an inner circumferential wall of the bearing


4


with an advance angle oil passage


202


, a retard angle oil passage


201


and the piston oil passage


203


which are formed in a ring shape and spaced in an axial direction thereof. The retard angle oil passage


201


and the advanced angle oil passage


202


are connected to the spool valve


230


to be driven electro-magnetically via oil passages


205


and


206


, respectively. The piston oil passage


203


is connected to the solenoid valve


240


via an oil passage


207


. A hydraulic pressure supply route through which the operation oil is supplied to the retard angle oil passage


201


and the advanced angle oil passage


202


is different from hydraulic pressure supply route through which the operation oil is supplied to the piston oil passage


203


. In the former route, the operation oil is hydraulically controlled by the spool valve


230


to be driven electro-magnetically and, in the latter route, the operation oil is hydraulically controlled by the solenoid valve


240


.




An oil supply passage


210


is connected to an oil pump


220


. The oil pump


220


is a mechanical pump rotatable with the engine. The oil pump


220


can supply the operation oil drawn up from a drain


221


to the retard angle oil passage


201


and the advanced angle oil passage


202


via the spool valve


230


and to the piston oil passage


203


via the solenoid valve


240


. An oil temperature sensor


250


detects temperature of the operation oil of the oil supply passage


210


.




The spool valve


230


is duty ratio controlled by an electrically control unit (ECU) for the engine (not shown). The spool valve


230


controls hydraulic pressure of the respective retard and advanced angle hydraulic chambers


51


to


54


and


55


to


58


in such a manner that reciprocating movement of a spool (not shown) allows or prohibits the oil passage


205


or the oil passage


206


to communicate with the oil supply passage


210


or the drain


221


.




The solenoid valve is also controlled by ECU. The oil passage


207


communicates with the oil supply passage


210


upon energizing the solenoid valve


240


and is opened to the drain


221


upon de-energizing the solenoid valve


240


.




As shown in

FIG. 2

, oil passages


61


,


62


,


63


and


64


that are formed in the vane rotor


15


communicate with the retard angle oil passage


201


via oil passages formed in the vane rotor


15


and the camshaft


3


. The oil passages


61


,


62


,


63


and


64


communicate with the retard angle hydraulic chambers


51


,


52


,


53


and


54


, respectively.




Oil passages


65


and


66


are formed in an end surface of the vane rotor


15


in contact with an axial end of the camshaft


3


and communicates with the advanced angle oil passage


202


via an oil passage


204


formed in the camshaft


3


. The oil passage


65


communicates with the advanced angle hydraulic chambers


56


and


57


and the oil passage


66


communicates with the advanced angle hydraulic chambers


55


and


58


.




With the construction mentioned above, the operation oil from the oil pump


22


can be supplied to the retard angle hydraulic chambers


51


,


52


,


53


and


54


, the advanced angle hydraulic chambers


55


,


56


,


57


and


58


and the piston chambers


40


,


41


,


48


and


49


and the operation oil can be ejected from the respective hydraulic chambers to the drain


221


.




An operation of the valve timing adjusting apparatus


1


is described.




When the solenoid valve


240


is energized at a normal engine operation, the operation oil is supplied to the piston chambers


40


,


41


,


48


and


49


from the piston oil passage


203


. As shown in

FIG. 4

, hydraulic pressures of the piston chambers


40


and


41


cause the lock piston


30


to pull out of the fitting hole


36


against biasing force of the spring


37


. Hydraulic pressures of the piston chambers


48


and


49


cause the restriction piston


44


to pull out of the restriction hole


45


against biasing force of the spring


46


. At this time, the vane rotor


15


is rotatable relatively to the housing


10


. Pressures applied to the respective retard and advanced angle hydraulic chambers are adjusted by a duty ratio control of the spool valve


230


so that angular phase of the camshaft


3


relative to the crankshaft is defined.




When an ignition key is turned on to stop the engine, the engine is generally in an idling operation state. In the idling operation state, the valve timing of the intake valve is set generally to an intermediate position between a middle position and the most retard angle position. Current for driving the spool valve


230


is controlled for a certain period just before the engine stops so as to cause the advanced angle oil passage


202


to communicate with the oil supply passage


210


so that the operation oil is supplied to the respective advanced angle hydraulic chambers. Since the retard angle oil passage


201


is opened to the drain


221


, the operation oil of the respective retard angle hydraulic chambers is ejected via the retard angle oil passage


201


. Accordingly, the vane rotor


15


rotates relatively to the housing


10


toward the middle position from the intermediate position between the middle position and the most retard angle position. Further, when the engine stops, the solenoid valve


240


is de-energized so that the piston oil passage


203


is opened to the drain


221


. Accordingly, the operation oil of the piston chambers


40


,


41


,


48


and


49


is ejected via the piston oil passage


203


. The lock piston


30


is moved toward the fitting hole


36


by the biasing force of the spring


37


and the restriction piston


44


is moved toward the restriction hole


45


by the biasing force of the spring


46


.




When the vane rotor


15


rotates relatively to the housing


10


to the middle position, the lock piston


30


is fitted in the fitting hole


36


so that the angular phase of the vane rotor


15


relative to the housing


10


is locked.




Retard and advanced angle responsive speed of rotating the vane rotor


15


relatively to the housing


10


, speed of inserting the lock piston


30


into the fitting hole


36


and speed of inserting the restriction piston


44


into the restriction hole


45


are variable according to changes of viscosity of the operation oil, that is, temperature and pressure of the operation oil. For example, as shown in

FIG. 5

, as the viscosity of the operation oil decreases with increase of temperature of the operation oil, the pressure of the operation oil decreases so that the retard and advanced angle responsive speed of rotating the vane rotor


15


relatively to the housing


10


becomes slower. Further, as the viscosity of the operation oil decreases with increase of temperature of the operation oil, the operation oil is more easily ejected from the piston chambers


40


,


41


,


48


and


49


so that moving speed of the lock piston


30


and moving speed of the restriction piston


44


become faster. On the other hand, as the pressure of the operation oil increases, the retard and advanced angle responsive speed becomes faster and the moving speed of the lock piston


30


and the moving speed of the restriction piston


44


become slower. Furthermore, speed of pulling the lock piston


30


out of the fitting hole


36


and speed of pulling the restriction piston


44


out of the restriction hole


45


are also changed according to changes of the temperature and pressure of the operation oil. In any way, the retard and advanced angle responsive speed of rotating the vane rotor relatively to the housing


10


varies inversely with the moving speeds of the lock and restriction pistons


30


and


44


when the temperature and pressure of the operation oil are changed. The moving speeds of the lock and restriction pistons


30


and


44


are substantially same. Further, since the operation oil is supplied to the piston chambers


40


,


41


,


48


and


49


via the same supply route from the same hydraulic pressure source, start timing of moving the lock piston


30


to be inserted into the fitting hole


36


is substantially same as start timing of moving the restriction piston


44


to be inserted into the restriction hole


45


.




If the spool valve


230


and the solenoid valve


240


are actuated substantially at the same time so that the start timing of moving the lock piston


30


to be inserted into the fitting hole


36


(lock start timing) or the start timing of moving the rock piston


30


to be pulled out of the fitting hole


36


(lock release start timing) is substantially same as the start timing of rotating the vane rotor


15


relatively to the housing


10


to a target position (rotation start timing), it sometimes happens that the lock piston


30


passes the fitting hole


36


before the lock piston


30


is fitted in the fitting hole


36


or the lock piston


30


can not be pulled out of the fitting hole


36


because the lock piston


30


is pressed against an inner wall of the fitting hole


36


.




According to the first embodiment, the lock start timing or the lock release start timing, which is controlled by the solenoid valve


240


, is retard by a given delay time from the rotation start timing, which is controlled by the spool valve


230


. The given delay time is decided with reference to a delay time map by sensor signals representing the temperature and pressure of the operation oil that are input to ECU. As shown in

FIGS. 7 and 8

, the given delay time is shorter with increase of the temperature of the operation oil and longer with increase of the pressure of the operation oil. Instead of the sensor signal from the oil temperature sensor


250


, a sensor signal from a water temperature sensor may be used. Further, instead of the sensor signal from a oil pressure sensor, a sensor signal from an engine revolution sensor may be used. The pressure of the operation oil increases with increase of the engine revolution and decreases with decrease of the engine revolution.





FIG. 10

shows a lock control routine for fitting the lock piston


30


in the fitting hole


36


. At Step


300


, it is determined whether or not there exists a lock mode at a time when the engine stops. Unless the lock mode exists, the routine ends. If the lock mode exists, the solenoid valve


240


is de-energized so that, as shown in

FIGS. 9A and 9B

, the lock piston


30


is urged toward the fitting hole


36


at Step


301


. The restriction piston


44


is also urged toward the restriction hole


45


substantially at the same time when the lock piston is urged.




If it is determined that the lock piston


30


can be fitted in the fitting hole


36


without retarding the rotation start timing from the lock start timing, for example, in a case that the angular phase of the vane rotor


15


relative to the housing


10


is at a position in a vicinity of the most retard angle position, that is, if it is determined that delay control for the spool valve


230


is not necessary, the vane rotor


15


is driven relatively to the housing


10


in an advanced angle direction by duty ratio controlling the spool valve


230


at Step


305


.




If it is determined that the delay control is necessary, the given delay time is defined from the delay time map based on input information representing the temperature and pressure of the operation oil at Step


303


. And, if it is determined that the given delay time has lapsed at Step


304


, the routine goes to Step


305


where the vane rotor


15


is driven relatively to the housing


10


in an advanced angle direction by duty ratio controlling the spool valve


230


. Since the lock piston


30


protrudes toward the fitting hole


36


, the lock piston


30


hits on the opening end of the fitting hole


36


on an advanced angle side so that the lock piston is confidently fitted in the fitting hole


36


.




Even if the lock piston


30


passes the fitting hole


36


, the restriction piston


44


hits on the end of the restriction hole


45


on a retard angle side since the vane rotor


15


is returned in retard angle direction by fluctuating torque that the camshaft


3


receives in a retard angle direction. Since the position where the restriction piston


44


hits on the end of the restriction hole on a retard angle side is the middle position, the lock piston


30


is confidently fitted in the the fitting hole


36


.




When the engine is cranked, the lock piston


30


is pulled out of the fitting hole


36


according to a lock release control routine shown in FIG.


12


. At first, it is determined at Step


310


whether or not a target angular phase of the vane rotor


15


relative to the housing


10


is outside a lock position that is the middle position, in another word, a position shifted from the lock position toward the most retard angle position or the most advanced angle position. If the target angular phase is at the lock position, not the position shifted from the lock position toward the most retard angle position or the most advanced angle position, this routine ends without pulling the lock piston


30


out of the fitting hole


36


.




If the target angular phase is at the position shifted from the lock position toward the most retard angle position or the most advanced angle position, the solenoid valve


240


is energized at Step


311


so that the operation oil is supplied to the piston chambers


40


,


41


,


48


and


49


. Next, the spool valve is duty ratio controlled so as to cause the vane rotor to receive hydraulic pressure in an advance angle direction at Step


312


and decrease the fluctuating torque that the vane rotor


15


receives in a retard angle direction so that the lock piston


30


is easily pulled out of the fitting hole


36


.




Then, the given delay time is defined from the delay time map based on input information representing the temperature and pressure of the operation oil and, if it is determined that the given delay time has lapsed at Step


313


, the target angular phase is set at Step


314


and the vane rotor


15


rotates relatively to the housing


10


to achieve the target angular phase.




According to the first embodiment, the start timing of rotating the vane rotor


15


relative to the housing


10


to the target angular phase is retard by the delay time defined by the temperature and pressure of the operation oil from the lock start timing of inserting the lock piston


30


into the fitting hole


36


or the lock release start timing of pulling the lock piston out of the fitting hole


36


. Since the lock piston is confidently fitted in the fitting hole


36


at the time of the engine stop, the engine can be cranked with timing of the intake valve most suitable for engine cranking, which results in preventing engine cranking failure. Further, the lock piston


30


can be easily pulled out of the fitting hole


36


.




In the first embodiment, the angular phase restriction means constituted by the restriction piston


44


, the restriction hole


45


, the spring


46


and piston chambers


48


and


49


may be omitted.




(Second Embodiment)




A valve timing adjusting apparatus according to a second embodiment is described with reference to

FIGS. 13

to


16


. According to the second embodiment, an oil supply route through which operation oil is supplied to the retard angle hydraulic chambers, the advanced angle hydraulic chamber and the piston chambers


40


and


41


, which is controlled by the spool valve


230


, is different from an oil supply route through which operation oil is supplied to the piston chambers


48


and


49


, which is controlled by the solenoid valve


240


.




At a normal engine operation, advanced angle hydraulic pressure is applied to the piston chamber


40


and retard angle hydraulic pressure is applied to the piston chamber


41


so that the rock piston


30


is pulled out of the fitting hole


36


. The advanced angle hydraulic pressure may be applied to the piston chamber


41


and the retard angle hydraulic pressure may be applied to the piston chamber


40


.




For example, in a case of rapidly reducing vehicle speed during a period when the vehicle is running at high and constant speed, it sometimes happens that, if the angular phase control near the most retard angle position is performed, the engine can not be normally operated because a valve overlap angle, that is, an angle by which a valve opening period of the intake valve overlaps with a valve opening period of the exhaust valve, does not meet the engine operating conditions. To prevent the abnormal condition of the engine mentioned above, it is preferable to perform the angular phase control within a range excluding a position near the most retard angle position in such a manner that the restriction piston


44


is urged to protrude into the restriction hole


45


by de-energizing the solenoid valve


240


and the restriction piston


44


is inserted into the restriction hole


45


.




The restriction piston


44


is inserted into the restriction hole


45


according to a control routine shown in FIG.


14


. At Step


320


, it is determined whether or not the restriction piston


44


should be inserted into the restriction hole


45


. Unless it is determined that the restriction piston


44


should be inserted into the restriction hole


45


, this routine ends. If it is determined that the restriction piston


44


should be inserted into the restriction hole


45


, a given delay time is defined from the delay time map based on input information representing the temperature and pressure of the operation oil and it is determined whether or not the given delay time lapsed at Step


321


. If it is determined that the given delay time has lapsed, the vane rotor


15


is controlled to rotate relatively to the housing


10


in a normal way to achieve the target angular phase at Step


322


. Unless it is determined that the given delay time has lapsed, it is determined at Step


323


whether or not the restriction piston


44


is positioned angularly outside the restriction hole


45


in a state that the vane rotor


15


rotates relatively to the housing


10


to achieve the target angular phase. Unless the restriction piston


44


is positioned angularly outside the restriction hole


45


, that is, if the restriction piston


44


is positioned angularly inside the restriction hole


45


, the routine goes to Step


322


where the normal angular phase control is performed.




If the restriction piston


44


is positioned angularly outside the restriction hole


45


, after the vane rotor


15


temporarily rotates relatively to the housing


10


to achieve a tentative target angular phase, as shown in

FIGS. 13A and 13B

, where the restriction piston


44


is positioned angularly inside the restriction hole and in a vicinity of an end of the restriction hole


45


on a retard angle side or on an advanced angle side at Step


324


, the routine goes to Step


321


. Since the vane rotor


15


moves to achieve the tentative target angular phase within the given delay time, the restriction piston


44


can be inserted into the restriction hole


45


without fail within the given delay time, as shown in FIG.


13


C. After the given delay time lapses, the normal angular phase control is performed. At this time, the angular phase is limited within a range defined by the end of the restriction hole


45


on a retard angle side and the other end of the restriction hole


45


on an advanced angle side.




Since, when the target angular phase calculated before the given delay time lapses is at the position where the restriction piston


44


is positioned angularly outside the restriction hole


45


, the vane rotor


15


temporarily rotates relatively to the housing


10


to achieve the tentative target angular phase within the given delay time, time necessary for rotating the vane rotor to the target angular phase after the given delay time lapses is shorter.





FIG. 16

shows a control routine for pulling the restriction piston


44


out of the restriction hole


45


as shown in FIG.


15


A.




At Step


330


, it is determined whether or not the target angular phase is at a position where the restriction piston


44


is outside the restriction hole


45


. If the target angular phase is at a position where the restriction piston


44


is not outside the restriction hole


45


but inside the restriction hole


45


, this routine ends. If the target angular phase is at the position where the restriction piston


44


is outside the restriction hole


45


, the solenoid valve is de-energized at Step


331


for pulling the restriction piston


44


out of the restriction hole


45


. A given delay time is defined from the delay time map based on input information representing the temperature and pressure of the operation oil and it is determined whether or not the given delay time lapsed at Step


332


. If it is determined that the given delay time has lapsed, the vane rotor


15


is controlled to rotate relatively to the housing


10


in a normal way to achieve the target angular phase at Step


333


. Unless it is determined that the given delay time has lapsed, the vane rotor


15


rotate to achieve a tentative target angular phase where the restriction piston


44


is positioned angularly inside the restriction hole


45


and in a vicinity of an end of the restriction hole on a retard angle side or on an advanced angle side at Step


334


. At this time, as shown in

FIG. 15C

, the restriction piston


44


can be easily pulled out of the restriction hole


45


since the restriction piston


44


is inside the restriction hole


45


and in a vicinity of the end of the restriction hole on a retard angle side or on an advanced angle side so that the restriction piston


44


is not in contact with inner wall of the restriction hole


45


.




In the second embodiment, the angular phase locking means constituted by the lock piston


30


, the fitting hole


36


, the spring


37


and piston chambers


40


and


41


may be omitted.




In the first and second embodiments, instead of the delay time map from which the given delay time is defined based on the sensor signals representing the temperature of pressure of the operation oil, numerical formula corresponding to the map may be used. The given delay time may be fixed value.




Further, the valve timing adjusting apparatus mentioned above may be applied to the exhaust valve instead of the intake valve or may be applied commonly to both of the intake valve and the exhaust valve.




Furthermore, instead of a structure that a direction in which the lock piston


30


is inserted toward the fitting hole


36


is an axial direction of the vane rotor


15


, the valve timing adjusting apparatus may have a structure that a direction in which the lock piston is inserted toward the fitting hole perpendicularly to the axial direction of the vane rotor. Moreover, the lock piston may be mounted on the housing and the fitting hole may be provided in the vane rotor.




Still further, instead of the chain sprocket through which the rotating drive force of the camshaft is transmitted to the camshaft, a timing pulley or a timing gear may be used for the same purpose. As an alternative, the vane rotor may receive the drive force of the crankshaft and the housing may be rotated together with the camshaft.




Further, instead of the vane type valve timing adjusting apparatus mentioned above, in a valve timing adjusting apparatus in which a drive force transmitting member having a helical spline engagement mechanism is disposed between the drive side rotating member rotatable with the crankshaft and the driven side rotating member rotatable with the camshaft and the angular phase of the driven side rotating member relative to the drive side rotating member is varied by hydraulically moving reciprocatingly the drive force transmitting member, the lock or restriction piston and the angular phase locking or restriction means may be provided.




Further, instead of the timing gear through which drive force of the crankshaft is transmitted to the camshaft, a timing pulley or a chain sprocket may be used.



Claims
  • 1. A valve timing adjusting apparatus disposed between a drive shaft of an internal combustion engine and a driven shaft causing an opening and closing operation of at least one of an intake valve and an exhaust valve and operative to change an angular phase of the driven shaft relative to the drive shaft so that opening and closing timing of the at least one of an intake valve and an exhaust valve may be varied, comprising:a drive side rotating member rotatable together with the drive shaft; a driven side rotating member rotatable together with the driven shaft, a rotation control pressure chamber operative to rotate the driven side rotating member relative to the drive side rotating member so that angular phase of the driven side rotating member relative to the drive side rotating member is controlled to a target position between the most retard angle position and the most advanced angle position in response to hydraulic pressure applied thereto; a lock piston provided in one of the driven and drive side rotating members; a fitting hole provided in the other of the driven and drive side rotating members; and an angular phase locking pressure chamber operative to execute one of first and second operations when hydraulic pressure is applied thereto and the other of the first and second operations when application of the hydraulic pressure thereto is released, the first operation being to insert the lock piston into the fitting hole so as to lock the angular phase of the driven side rotating member relative to the drive side rotating member to a middle position between the most retard angle position and the most advanced angle position, and the second operation being to pull the lock piston out of the fitting hole so as to release lock of the angular phase of the driven side rotating member relative to the drive side rotating member at the middle position, wherein a supply route of the hydraulic pressure to the rotation control pressure chamber is different from that to the angular phase locking pressure chamber and, when at least one of the first and second operations is executed, start timing of rotation of the driven side rotating member relative to the drive side rotating member so as to change the angular phase of the driven side rotating member relative to the drive side rotating member to the target position is retard by a given delay time from start timing of execution of the at least one of the first and second operations.
  • 2. A valve timing adjusting apparatus according to claim 1, wherein the lock piston is provided at an axial end thereof with a tapered portion whose diameter is smaller toward the round hole, the fitting hole is provided at an opening end thereof with a chamfering portion whose diameter is larger toward the piston, and, when the first operation is executed, the given delay time by which the start timing of rotation of the driven side rotating member relative to the drive side rotating member is retard from the start timing of execution of the first operation is larger than time required for the tapered portion to pass the chamfering portion after the first operation starts.
  • 3. A valve timing adjusting apparatus according to claim 1, wherein the start timing of rotation of the driven side rotating member relative to the drive side rotating member is retard by a first given delay time from the start timing of execution of the first operation and by a second given delay time from start timing of execution of the second operation.
  • 4. A valve timing adjusting apparatus according to claim 1, wherein, when the second operation is executed, the start timing of rotation of the driven side rotating member relative to the drive side rotating member is retard by the given delay time from the start timing of execution of the second operation.
  • 5. A valve timing adjusting apparatus according to claim 4, wherein, after the second operation starts, the hydraulic pressure is applied to the rotation control pressure chamber in such a manner that the angular phase of the driven side rotating member relative to the drive side rotating member is kept at the middle position between the most retard angle position and the most advanced angle position or temporarily moved to a position slightly shifted from the middle position toward the advanced angle position before the given delay time lapses.
  • 6. A valve timing adjusting apparatus according to claim 1, wherein the given delay time by which the start timing of rotation of the driven side rotating member relative to the drive side rotating member is retard from the start timing of execution of the at least one of the first and second operations is determined by sensor signals representing pressure and temperature of fluid applied to at least one of the rotation control pressure chamber and the angular phase locking pressure chamber.
  • 7. A valve timing adjusting apparatus according to claim 1, further comprising:a restriction piston provided in one of the driven and drive side rotating members; a restriction hole formed in shape of an arc extending within a given angular range and provided in the other of the driven and drive side rotating members; and an angular phase restriction pressure chamber operative to execute one of third and fourth operations when hydraulic pressure is applied thereto and the other of the third and fourth operations when application of the hydraulic pressure thereto is released, the third operation being to insert the restriction piston into the restriction hole so as to restrict rotation of the driven side rotating member relative to the drive side rotating member within the given angular range and the fourth operation being to pull the restriction piston out of the restriction hole so as to release restriction of rotation of the driven side rotating member relative to the drive side rotating member within the given angular range, wherein a supply route of the hydraulic pressure to the angular phase restriction pressure chamber is same as that to the angular phase locking pressure chamber, an end of the given angular range is at a position corresponding to the middle position between the most retard angle position and the most advanced angle position and the other end of the given angular range is at a position away from the middle position toward the most advanced angle position and, when the third operation is executed together with the first operation, the restriction piston abuts on the end of the given angular range within the restriction hole.
  • 8. A valve timing adjusting apparatus according to claim 1, further comprising:a mechanical pump rotatable together with the engine for supplying the hydraulic pressure via the supply routes to the rotation control pressure chamber and the angular phase locking pressure chamber.
  • 9. A valve timing adjusting apparatus according to claim 1, wherein one of the driven and drive side rotating members is a housing having an accommodation chamber and the other of the driven and drive side rotating members is a vane rotatable within a defined angular range in the housing and having a partition with which the accommodation chamber is separated into two rooms one of which is a retard angle pressure chamber and the other of which is an advanced angle pressure chamber, whereby the vane is rotated relatively to the housing by controlling the hydraulic pressures applied to the respective retard and advanced angle pressure chambers.
  • 10. A valve timing adjusting apparatus disposed between a drive shaft of an internal combustion engine and a driven shaft causing an opening and closing operation of at least one of an intake valve and an exhaust valve and operative to change an angular phase of the driven shaft relative to the drive shaft so that opening and closing timing of the at least one of an intake valve and an exhaust valve may be varied, comprising:a drive side rotating member rotatable together with the drive shaft; a driven side rotating member rotatable together with the driven shaft, a rotation control pressure chamber operative to rotate the driven side rotating member relative to the drive side rotating member so that angular phase of the driven side rotating member relative to the drive side rotating member is controlled to a target position between the most retard angle position and the most advanced angle position in response to hydraulic pressure applied thereto; a restriction piston provided in one of the driven and drive side rotating members; a restriction hole formed in shape of an arc extending within a given angular range and provided in the other of the driven and drive side rotating members, an end of the restriction hole constituting a retard angle side end and the other end thereof constituting an advance angle side end; and an angular phase restriction pressure chamber operative to execute one of first and second operations when hydraulic pressure is applied thereto and the other of the first and second operations when application of the hydraulic pressure thereto is released, the first operation being to insert the restriction piston into the restriction hole so as to restrict rotation of the driven side rotating member relative to the drive side rotating member within the given angular range and the second operation being to pull the restriction piston out of the restriction hole so as to release restriction of rotation of the driven side rotating member relative to the drive side rotating member within the given angular range, wherein a supply route of the hydraulic pressure to the rotation control pressure chamber is different from that to the angular phase restriction pressure chamber and, when at least one of the first and second operations is executed, start timing of rotation of the driven side rotating member relative to the drive side rotating member so as to change the angular phase of the driven side rotating member relative to the drive side rotating member to the target position is retard by a given delay time from start timing of execution of the at least one of the first and second operations.
  • 11. A valve timing adjusting apparatus according to claim 10, wherein, when the first operation is executed, the hydraulic pressure is applied to the rotation control pressure chamber in such a manner that, if the restriction piston is outside the given angular range of the restriction hole, the angular phase of the driven side rotating member relative to the drive side rotating member is temporarily moved to a position slightly inside the given angular range of the restriction hole before the given delay time lapses, whereby, when the driven side rotating member is rotated relatively to the drive side rotating member after the given delay time lapses, the target position of the angular phase of the driven side rotating member relative to the drive side rotating member is restricted within the given angular range since the restriction piston abuts on the retard angle side end or the advanced angle side end.
  • 12. A valve timing adjusting apparatus according to claim 10, wherein the start timing of rotation of the driven side rotating member relative to the drive side rotating member is retard by a first given delay time from the start timing of execution of the first operation and by a second given delay time from start timing of execution of the second operation.
  • 13. A valve timing adjusting apparatus according to claim 10, wherein, when the second operation is executed, the start timing of rotation of the driven side rotating member relative to the drive side rotating member is retard by the given delay time from the start timing of execution of the second operation.
  • 14. A valve timing adjusting apparatus according to claim 13, wherein, after the second operation starts, the hydraulic pressure is applied to the rotation control pressure chamber in such a manner that, before the given delay time lapses, the angular phase of the driven side rotating member relative to the drive side rotating member is temporarily moved to a position slightly away inward from the retard angle side end or the advanced angle side end of the restriction hole on which the restriction piston abuts so as to pull smoothly the restriction piston out of the restriction hole.
  • 15. A valve timing adjusting apparatus according to claim 10, wherein the given delay time by which the start timing of rotation of the driven side rotating member relative to the drive side rotating member is retard from the start timing of execution of the at least one of the first and second operations is determined by sensor signals representing pressure and temperature of fluid applied to at least one of the rotation control pressure chamber and the angular phase restriction pressure chamber.
  • 16. A valve timing adjusting apparatus according to claim 10, further comprising:a lock piston provided in one of the driven and drive side rotating members; a fitting hole provided in the other of the driven and drive side rotating members; and an angular phase locking pressure chamber operative to execute one of third and fourth operations when hydraulic pressure is applied thereto and the other of the third and fourth operations when application of the hydraulic pressure thereto is released, the third operation being to insert the lock piston into the fitting hole so as to lock the angular phase of the driven side rotating member relative to the drive side rotating member to a given position within the given angular range of the restriction hole and the fourth operation being to pull the lock piston out of the fitting hole so as to release lock of the angular phase of the driven side rotating member relative to the drive side rotating member at the given position, wherein a supply route of the hydraulic pressure to the angular phase locking pressure chamber is same as that to the rotation control pressure chamber.
  • 17. A valve timing adjusting apparatus according to claim 10, further comprising:a mechanical pump rotatable together with the engine for supplying the hydraulic pressure via the supply routes to the rotation control pressure chamber and the angular phase restriction pressure chamber.
  • 18. A valve timing adjusting apparatus according to claim 10, wherein one of the driven and drive side rotating members is a housing having an accommodation chamber and the other of the driven and drive side rotating members is a vane rotatable within a defined angular range in the housing and having a partition with which the accommodation chamber is separated into two rooms one of which is a retard angle pressure chamber and the other of which is an advanced angle pressure chamber, whereby the vane is rotated relatively to the housing by controlling the hydraulic pressures applied to the respective retard and advanced angle pressure chambers.
Priority Claims (1)
Number Date Country Kind
2002-088300 Mar 2002 JP
US Referenced Citations (4)
Number Name Date Kind
6058897 Nakayoshi May 2000 A
6505586 Sato et al. Jan 2003 B1
6634329 Kusano et al. Oct 2003 B2
20020139332 Takenaka Oct 2002 A1