JP6027494B2 - Control device for variable valve timing mechanism - Google Patents

Description

  The present invention relates to a control device for a variable valve timing mechanism that changes a relative rotational phase angle of a camshaft with respect to a crankshaft within a variable range restricted by a stopper.

  Patent Document 1 discloses an electric valve timing variable device that adjusts a relative rotational phase angle of a camshaft with respect to a crankshaft by an electric motor between a most retarded angle stopper and a most advanced angle stopper.

JP 2013-033691 A

In a variable valve timing mechanism in which the variable range of the relative rotational phase angle of the camshaft relative to the crankshaft is regulated by a stopper, when the command value (target value) is set at a position close to the stopper, the actual relative rotational phase angle is If an overshoot that approaches the stopper position beyond the command value (target value) occurs, a stopper collision may occur and the stopper may be damaged.
Here, it is possible to suppress the stopper collision by narrowing the control range of the relative rotational phase angle in anticipation of overshoot and changing the command value (target value) within the control range, but the control range for the movable range is excessive. There is a problem that the internal combustion engine performance cannot be sufficiently improved by changing the valve timing.

  The present invention has been made in view of the above problems, and an object of the present invention is to provide a control device for a variable valve timing mechanism capable of suppressing the control range of the relative rotational phase angle while suppressing stopper collision. .

Therefore, the present invention is a control device for a variable valve timing mechanism that changes a relative rotational phase angle of a camshaft with respect to a crankshaft of an internal combustion engine within a variable range regulated by a stopper, and the relative rotational phase angle is variable. when out of a predetermined phase angle range which is contained in the range, with a response speed reduction means for reducing the response speed of the relative rotational phase angle than when the is within a predetermined phase angle range, the response speed lowering means Is configured to change at least one of the phase angle for starting the decrease in the response speed and the degree of decrease in the response speed in accordance with the change state of the relative rotational phase angle .

  According to the above invention, the overshoot can be suppressed by reducing the response speed of the phase angle in the vicinity of the stopper, whereby the control range of the relative rotational phase angle can be set as wide as possible while suppressing the stopper collision. This can sufficiently improve the performance of the internal combustion engine by changing the valve timing.

1 is a system configuration diagram of an internal combustion engine in an embodiment of the present invention. It is sectional drawing which shows the variable valve timing mechanism in embodiment of this invention. It is sectional drawing which shows the variable valve timing mechanism in embodiment of this invention, Comprising: It is the sectional view on the AA line of FIG. It is sectional drawing which shows the variable valve timing mechanism in embodiment of this invention, Comprising: It is the BB sectional drawing of FIG. It is a figure for demonstrating the area | region of the relative rotational phase angle in embodiment of this invention. It is a flowchart which shows the setting process of the target value of a relative rotation phase angle in embodiment of this invention. It is a time chart which shows the example of a characteristic of target value SLTA for soft landing in the embodiment of the present invention. It is a flowchart which shows the setting process of the target value of a relative rotation phase angle in embodiment of this invention. It is a diagram which illustrates the correlation with variation | change_quantity (DELTA) TAB and initial value INA in embodiment of this invention. It is a diagram which illustrates the correlation with variation | change_quantity (DELTA) TAB and variation | change_rate (DELTA) A in embodiment of this invention. It is a diagram which illustrates the correlation with change rate (DELTA) RA and initial value INA in embodiment of this invention. It is a diagram which illustrates the correlation of change speed RA and change speed (DELTA) A in embodiment of this invention.

Embodiments of the present invention will be described below.
FIG. 1 is a diagram showing an example of a vehicle internal combustion engine to which a control device for a variable valve timing mechanism according to the present invention is applied.
The intake duct 102 of the internal combustion engine 101 is provided with an intake air amount sensor 103 that detects the intake air flow rate QA of the internal combustion engine 101.

The intake valve 105 opens and closes the intake port of the combustion chamber 104 of each cylinder, and the intake port 102a on the upstream side of the intake valve 105 includes a fuel injection valve 106 for each cylinder.
The internal combustion engine 101 can be an in-cylinder direct injection internal combustion engine in which the fuel injection valve 106 directly injects fuel into the combustion chamber 104.

The fuel injected from the fuel injection valve 106 is sucked together with air into the combustion chamber 104 via the intake valve 105 and ignited and burned by spark ignition by the spark plug 107, and the pressure by the combustion causes the piston 108 to be applied to the crankshaft 109. By pushing down, the crankshaft 109 is rotationally driven.
Further, the exhaust valve 110 opens and closes the exhaust port of the combustion chamber 104, and the exhaust valve 110 is opened so that the exhaust gas is discharged to the exhaust pipe 111.

A catalytic converter 112 having a three-way catalyst or the like is installed in the exhaust pipe 111, and the catalytic converter 112 purifies the exhaust gas.
The intake valve 105 opens with the rotation of the intake camshaft 115a driven to rotate by the crankshaft 109, and the exhaust valve 110 opens with the rotation of the exhaust camshaft 115b driven to rotate by the crankshaft 109. To do.

The variable valve timing mechanism 114 changes the relative rotational phase angle of the intake camshaft 115a with respect to the crankshaft 109 by means of an electric actuator (electric motor), so that the phase of the valve operating angle of the intake valve 105 (the opening timing IVO of the intake valve 105). And the closing timing IVC) is an electric variable valve timing mechanism (electric VTC) that continuously changes the advance angle direction and the retard angle direction.
Each ignition plug 107 is directly attached with an ignition module 116 that supplies ignition energy to the ignition plug 107. The ignition module 116 includes an ignition coil and a power transistor that controls energization of the ignition coil.

  An electronic control unit (ECU) 201 includes a microcomputer, inputs signals from various sensors and switches, and performs arithmetic processing in accordance with a program stored in advance in a memory, whereby a fuel injection valve 106, a variable valve timing mechanism 114, a control device (control unit) that calculates and outputs operation amounts of various devices such as the ignition module 116.

  The electronic control unit 201 receives the output signal of the intake air amount sensor 103 and also detects the depression amount (accelerator opening ACC) of the crank angle sensor 203 that outputs the rotation angle signal POS of the crankshaft 109 and the accelerator pedal 207. Installed in the accelerator opening sensor 206, the cam angle sensor 204 that outputs the rotation angle signal CAM of the intake camshaft 115a, the water temperature sensor 208 that detects the temperature TW of the cooling water of the internal combustion engine 101, and the exhaust pipe 111 upstream of the catalytic converter 112 Then, an output signal from an air-fuel ratio sensor 209 or the like that detects an air-fuel ratio AF based on the oxygen concentration in the exhaust gas is input, and further, an ignition switch (IGN switch) 205 that is a main switch for operating and stopping the internal combustion engine 101. Input the signal.

2 to 4 show an example of the structure of the variable valve timing mechanism 114.
The structure of the variable valve timing mechanism 114 is not limited to that illustrated in FIGS. 2 to 4, and a known variable valve timing mechanism that changes the relative rotational phase angle of the camshaft with respect to the crankshaft is appropriately employed. It is also possible to provide a variable valve timing mechanism that makes the valve timing of the exhaust valve 110 variable.

  The variable valve timing mechanism 114 is rotatably supported by a timing sprocket 1 that is a driving rotating body that is rotationally driven by the crankshaft 109 of the internal combustion engine 101 and a cylinder head via a bearing 44, and is transmitted from the timing sprocket 1. The intake camshaft 115a that rotates by the rotational force, the cover member 3 that is disposed at a position in front of the timing sprocket 1 and is fixed to the chain cover 40 that is a fixing portion by bolts, the timing sprocket 1 and the intake camshaft 115a. And a phase changing mechanism 4 that changes the relative rotational phase angle of the intake camshaft 115a with respect to the timing sprocket 1.

The timing sprocket 1 is composed of a sprocket body 1a and a gear portion 1b that is integrally provided on the outer periphery of the sprocket body 1a and receives a rotational force from the crankshaft 109 via a wound timing chain 42. Yes.
In addition, the timing sprocket 1 is interposed between a circular groove 1c formed on the inner peripheral side of the sprocket body 1a and an outer periphery of a flange portion 2a provided integrally with the front end portion of the intake camshaft 115a. A ball bearing 43 rotatably supports the intake camshaft 115a.

An annular protrusion 1e is integrally formed on the outer peripheral edge of the front end portion of the sprocket body 1a.
At the front end portion of the sprocket body 1a, there are an annular member 19 that is coaxially positioned on the inner peripheral side of the annular protrusion 1e, and has an inner tooth 19a that is a wavy engagement portion on the inner periphery, and an annular plate 6 The bolts 7 are fastened together from the axial direction.
Further, as shown in FIG. 4, a stopper convex portion 1d, which is an arcuate engaging portion, is formed on a part of the inner peripheral surface of the sprocket body 1a up to a predetermined length range along the circumferential direction.

A cylindrical housing 5 protruding forward in a state of covering each component of a speed reducer 8 and an electric motor 12 described later of the phase changing mechanism 4 is fixed to the outer periphery of the front end side of the plate 6 by bolts 11.
The housing 5 is integrally formed of an iron-based metal and functions as a yoke. The housing 5 integrally has an annular plate-shaped holding portion 5a on the front end side, and the entire outer peripheral side including the holding portion 5a is a cover member. 3 are arranged so as to be covered with a predetermined gap.

The intake camshaft 115 a has a drive cam (not shown) that opens the intake valve 105 on the outer periphery, and a driven member 9 that is a driven rotating body at the front end portion is coupled from the axial direction by a cam bolt 10. .
Further, as shown in FIG. 4, a stopper concave groove 2b, which is a locking portion into which the stopper convex portion 1d of the sprocket body 1a is engaged, is formed in the flange portion 2a of the intake camshaft 115a along the circumferential direction. ing.

  The stopper concave groove 2b is formed in an arc shape having a predetermined length in the circumferential direction, and both end edges of the stopper convex portion 1d rotated in this length range abut against the circumferential opposite edges 2c and 2d, respectively. As a result, the relative rotational position of the intake camshaft 115a relative to the timing sprocket 1 on the maximum advance angle side and the maximum retard angle side is regulated. That is, the angle range in which the stopper convex portion 1d can move in the stopper groove 2b is a variable range of the relative rotation phase angle of the intake camshaft 115a with respect to the crankshaft 109.

The cam bolt 10 is formed integrally with the flange-shaped seating surface portion 10c at the end of the head portion 10a on the shaft portion 10b side, and is formed on the outer periphery of the shaft portion 10b from the end portion of the intake camshaft 115a to the inner axial direction. A male screw portion that is screwed onto the female screw portion is formed.
The driven member 9 is integrally formed of an iron-based metal material, and as shown in FIG. 3, a disk portion 9a formed on the front end side, and a cylindrical cylindrical portion 9b formed integrally on the rear end side It is composed of

The disc portion 9a is integrally provided with an annular step projection 9c having substantially the same outer diameter as that of the flange portion 2a of the intake camshaft 115a at a substantially central position in the radial direction of the rear end surface. The outer peripheral surface of the step projection 9c and the flange portion 2a are integrally provided. Of the third ball bearing 43 is inserted into the inner periphery of the inner ring 43a. The outer ring 43b of the third ball bearing 43 is press-fitted and fixed to the inner peripheral surface of the circular groove 1c of the sprocket body 1a.
A retainer 41 for holding a plurality of rollers 34 is integrally provided on the outer peripheral portion of the disc portion 9a.

The retainer 41 is formed by projecting from the outer peripheral portion of the disc portion 9a in the same direction as the cylindrical portion 9b, and is formed by a plurality of elongated protrusion portions 41a having predetermined gaps at substantially equal intervals in the circumferential direction. Has been.
The cylindrical portion 9b has a through hole 9d through which the shaft portion 10b of the cam bolt 10 is inserted in the center, and a first needle bearing 30 is provided on the outer peripheral side.

The cover member 3 is composed of a cover body 3a that is integrally formed of a synthetic resin material and swells in a cup shape, and a bracket 3b that is integrally provided on the outer periphery of the rear end of the cover body 3a.
The cover body 3a is disposed so as to cover the front end side of the phase change mechanism 4, that is, to cover almost the entire rear end side from the holding portion 5b in the axial direction of the housing 5 with a predetermined gap. On the other hand, the bracket 3b is formed in a substantially annular shape, and bolt insertion holes 3f are formed through the six boss portions.

The cover member 3 has a bracket 3b fixed to the chain cover 40 via a plurality of bolts 47, and inner and outer double slip rings 48a and 48b are provided on the inner peripheral surface of the front end 3c of the cover body 3a. It is buried and fixed with the inner end face exposed.
Furthermore, the upper end of the cover member 3 is provided with a connector portion 49 to which a connector terminal 49a connected to the slip rings 48a and 48b via a conductive member is fixed. The connector terminal 49a is energized or de-energized from a battery power supply (not shown) via the electronic control unit 201.

A large-diameter first oil seal 50 as a seal member is interposed between the inner peripheral surface on the rear end side of the cover body 3a and the outer peripheral surface of the housing 5.
The first oil seal 50 is formed in a substantially U-shaped cross section, and a cored bar is embedded in the synthetic rubber base material, and the annular base 50a on the outer peripheral side is the rear end of the cover member 3a. It is fitted and fixed in a circular groove 3d formed on the inner peripheral surface of the.
In addition, a seal surface 50b that contacts the outer peripheral surface of the housing 5 is integrally formed on the inner peripheral side of the annular base portion 50a.

The phase changing mechanism 4 includes an electric motor 12 disposed substantially on the coaxial front end side of the intake camshaft 115a, and a speed reducer 8 that reduces the rotational speed of the electric motor 12 and transmits it to the intake cam camshaft 115a. ing.
The electric motor 12 is, for example, a brushed DC motor, which is a housing 5 that is a yoke that rotates integrally with the timing sprocket 1, and a motor shaft 13 that is an output shaft that is rotatably provided inside the housing 5. A pair of semicircular arc permanent magnets 14 and 15 fixed to the inner peripheral surface of the housing 5 and a stator 16 fixed to the inner bottom surface side of the housing holding portion 5a are provided.

The motor shaft 13 is formed in a cylindrical shape and functions as an armature. An iron core rotor 17 having a plurality of poles is fixed to the outer periphery at a substantially central position in the axial direction, and an electromagnetic coil is provided on the outer periphery of the iron core rotor 17. 18 is wound.
Further, a commutator 20 is press-fitted and fixed to the outer periphery of the front end portion of the motor shaft 13, and an electromagnetic coil 18 is connected to each segment divided into the same number as the number of poles of the iron core rotor 17. .

The motor shaft 13 includes a needle bearing 28 serving as a first bearing on the outer peripheral surface of the shaft portion 10b on the head 10a side of the cam bolt 10 and a fourth ball bearing serving as a bearing disposed on an axial side portion of the needle bearing 28. 35 is rotatably supported via 35.
A cylindrical eccentric shaft portion 30 constituting a part of the speed reducer 8 is integrally provided at the rear end portion of the motor shaft 13 on the intake camshaft 115a side.

Further, a second oil seal 32 that is a friction member for preventing leakage of lubricating oil from the inside of the reduction gear 8 into the electric motor 12 is provided between the outer peripheral surface of the motor shaft 13 and the inner peripheral surface of the plate 6. It has been. The second oil seal 32 is configured to give a frictional resistance against the rotation of the motor shaft 13 by the inner peripheral portion being in elastic contact with the outer peripheral surface of the motor shaft 13.
The speed reducer 8 includes an eccentric shaft portion 30 that performs eccentric rotational motion, a second ball bearing 33 that is a second bearing provided on the outer periphery of the eccentric shaft portion 30, and a roller provided on the outer periphery of the second ball bearing 33. 34, a holder 41 that allows the roller 34 to move in the rolling direction while holding the roller 34 in the rolling direction, and a driven member 9 that is integral with the holder 41.

In the eccentric shaft portion 30, the shaft center of the cam surface formed on the outer peripheral surface is slightly eccentric in the radial direction from the shaft center X of the motor shaft 13. The second ball bearing 33 and the roller 34 are configured as a planetary meshing portion.
The second ball bearing 33 is formed in a large diameter, and is disposed so as to substantially overlap at the radial position of the first needle bearing 28, and the inner ring 33 a is press-fitted and fixed to the outer peripheral surface of the eccentric shaft portion 30. In addition, the roller 34 is always in contact with the outer peripheral surface of the outer ring 33b.

An annular gap C is formed on the outer peripheral side of the outer ring 33, and the entire second ball bearing 33 can move in the radial direction along with the eccentric rotation of the eccentric shaft portion 30, that is, can move eccentrically. It has become.
Each roller 34 is fitted in the internal teeth 19a of the annular member 19 while moving in the radial direction along with the eccentric movement of the second ball bearing 33, and is guided in the circumferential direction by the protrusion 41a of the cage 41 in the radial direction. Is designed to swing.

Lubricating oil is supplied into the reduction gear 8 by lubricating oil supply means.
Lubricating oil supply means is formed inside the bearing 44 of the cylinder head, and is formed in the direction of the internal axis of the intake camshaft 115a, an oil supply passage 44a for supplying lubricating oil from a main oil gallery (not shown), An oil supply hole 48 communicated with the oil supply passage 44a via a groove groove, and is formed so as to penetrate the driven member 9 in the inner axial direction. One end opens into the oil supply hole 48, and the other end is connected to the first needle bearing 28. A small-diameter oil supply hole 45 opened in the vicinity of the second ball bearing 33 and three large-diameter oil discharge holes, not shown, that are also formed through the driven member 9 are formed.

Hereinafter, the operation of the variable valve timing mechanism 114 will be described. First, when the crankshaft 109 of the internal combustion engine 101 is rotationally driven, the timing sprocket 1 rotates via the timing chain 42, and the housing 5 and the annular member 19 are rotated by the rotational force. The electric motor 12 rotates synchronously via the plate 6.
On the other hand, the rotational force of the annular member 19 is transmitted from the roller 34 to the intake camshaft 115a via the retainer 41 and the driven member 9. As a result, the cam of the intake camshaft 115a opens and closes the intake valve 105.

When the variable valve timing mechanism 114 is driven to change the relative rotation phase angle of the intake camshaft 115a with respect to the crankshaft 109 (the valve timing of the intake valve 105), the electronic control unit 201 uses the slip rings 48a, 48b, etc. The electromagnetic coil 17 of the electric motor 12 is energized via. As a result, the motor shaft 13 is rotationally driven, and the rotational force of this rotational force is transmitted to the intake camshaft 115a via the speed reducer 8.
That is, when the eccentric shaft portion 30 rotates eccentrically with the rotation of the motor shaft 13, each roller 34 is guided by one of the annular members 19 while being radially guided by the protrusion 41 a of the retainer 41 for each rotation of the motor shaft 13. The robot moves over the inner teeth 19a while rolling to other adjacent inner teeth 19a, and repeats this in order to make rolling contact in the circumferential direction.

The rotational force is transmitted to the driven member 9 while the rotation of the motor shaft 13 is decelerated by the rolling contact of the rollers 34. The reduction ratio at this time can be arbitrarily set according to the number of rollers 34 or the like.
As a result, the intake camshaft 115a rotates forward and backward relative to the timing sprocket 1 and the relative rotational phase angle is converted, and the opening / closing timing of the intake valve 105 is controlled to be advanced or retarded.

The maximum position restriction (angular position restriction) of forward and reverse relative rotation of the intake camshaft 115a with respect to the timing sprocket 1 is such that each side surface of the stopper convex portion 1d is set to one of the opposing surfaces 2c and 2d of the stopper concave groove 2b. This is done by abutting.
That is, the driven member 9 rotates in the same direction as the rotation direction of the timing sprocket 1 as the eccentric shaft portion 30 rotates eccentrically, so that one side surface of the stopper convex portion 1d is opposed to one side of the stopper groove 2b. A further rotation in the same direction is restricted by contacting the surface 1c. As a result, the intake camshaft 115a has its relative rotational phase angle with respect to the timing sprocket 1 changed to the maximum advance side.

On the other hand, when the driven member 9 rotates in the direction opposite to the rotation direction of the timing sprocket 1, the other side surface of the stopper convex portion 1d abuts against the opposite surface 2d on the other side of the stopper concave groove 2b and further in the same direction. Rotation is regulated. Thereby, the relative rotation phase of the intake camshaft 115a with respect to the timing sprocket 1 is changed to the maximum on the retard side.
As described above, the electronic control unit 201 controls the relative rotation phase angle of the intake camshaft 115a with respect to the crankshaft 109 through the energization control of the electric motor (electric actuator) 12 of the variable valve timing mechanism 114.

The electronic control unit 201 calculates a target phase angle TA (target advance amount, target valve timing) based on the operating state of the internal combustion engine 101 (for example, engine load, engine speed, engine temperature, starting state, etc.). Based on the output signal of the crank angle sensor 203 and the output signal of the cam angle sensor 204, the actual relative rotational phase angle RA of the intake camshaft 115a with respect to the crankshaft 109 is detected.
Then, the electronic control unit 201 is electrically driven by, for example, proportional-integral control based on a deviation between the target phase angle TA and the actual relative rotational phase angle RA so that the actual relative rotational phase angle RA approaches the target phase angle TA. The energization of the motor 12 is feedback controlled.

Here, the variable range VAA of the relative rotation phase angle of the intake camshaft 115a with respect to the crankshaft 109 is caused by the contact of each side surface of the stopper convex portion 1d with one of the opposing surfaces 2c and 2d of the stopper groove 2b. Be regulated.
Therefore, in the control of the relative rotational phase angle, the electronic control unit 201 has a phase angle within the control range CAA included in the variable range VAA by the mechanical stopper configured by the stopper convex portion 1d and the stopper concave groove 2b. Thus, the target phase angle TA is limited so that the target phase angle TA that causes the stopper to come into contact is not set.

That is, the electronic control unit 201 includes an advance side control limiter ACL that is set on the retard side with respect to the maximum advance position AL by the stopper, and a retard angle that is set on the advance side with respect to the maximum retard position RL by the stopper. A rotation phase angle range sandwiched between the side control limiters RCL is defined as a control range CAA.
The electronic control device 201 sets the phase angle of the advance side control limiter ACL when the target phase angle TA set according to the operation state of the internal combustion engine 101 is more advanced than the advance side control limiter ACL. When the target phase angle TA set according to the operating state of the internal combustion engine 101 is set to the retard side with respect to the retard side control limiter RCL, the phase angle of the retard side control limiter RCL is set to the target phase angle TA. As described above, the target phase angle TA is limited within the control range CAA.

The target phase angle TA based on the operating state of the internal combustion engine 101 can be set within the control range CAA. For example, the data of the target phase angle TA stored in the map is previously stored in the control range CAA. Can be set as a value within.
Furthermore, the electronic control unit 201 is configured to detect the actual phase angle RA toward the target phase angle TA in a region outside the high response control range HRA included in the control range CAA as compared with the case in the high response control range HRA. Control to reduce the response speed of the change in the frequency (hereinafter referred to as soft landing control) is performed.

FIG. 5 shows the correlation among the variable range VAA, the control range CAA, and the high response control range HRA.
Here, the range between the maximum advance angle position AL by the stopper and the maximum retard angle position RL by the stopper is the relative rotation phase angle variable range VAA, which is delayed by a predetermined phase angle ΔPAL1 from the maximum advance angle position AL by the stopper. The angle position on the angle side is set as the advance angle side control limiter ACL, and the angle position on the advance angle side by the predetermined phase angle ΔPRL1 from the maximum delay angle position RL by the stopper is set as the retard angle side control limiter RCL.

A range narrower than the variable range VAA sandwiched between the advance side control limiter ACL and the retard side control limiter RCL is set as the control range CAA, and in setting the target phase angle TA, the target phase angle is within the control range CAA. Limit TA.
Predetermined phase angles ΔPAL1 and ΔPRL1 suppress the occurrence of stopper contact even when there are variations in variable valve timing mechanism 114, detection variations in actual phase angle RA, and periodic variations in actual phase angle RA due to cam torque. Pre-adapted as possible values. That is, when the actual phase angle RA is converged to the target phase angle TA within the control range CAA, the stopper contact does not occur even if there is a periodic variation of the actual phase angle RA due to various variations and cam torque. The margins provided between the stopper position and the control limiters ACL, RCL are the predetermined phase angles ΔPAL1, ΔPRL1.

In addition, when the phase angle close to the advance side control limiter ACL or the retard side control limiter RCL within the control range CAA (in other words, the phase angle close to the mechanical stopper position) is set as the target phase angle TA, the actual phase In the control for bringing the angle RA closer to the target phase angle TA, when an overshoot occurs in which the actual phase angle RA changes beyond the target phase angle TA, the side surface of the stopper convex portion 1d collides with the opposing surfaces 2c and 2d of the stopper concave groove 2b. In addition, there is a possibility that the stopper convex portion 1d, the stopper concave groove 2b and the like are damaged.
Therefore, the electronic control unit 201 determines the angle position that is retarded by a predetermined phase angle ΔPAL2 from the advance side control limiter ACL that defines the control range CAA as the high response advance limit position HRAL, and sets the control range CAA as the control range CAA. The angle position on the advance side by a predetermined phase angle ΔPRL2 from the prescribed retard side control limiter RCL is defined as the high response delay limit position HRRL.

Then, the electronic control unit 201 defines a range enclosed by the control range CAA narrower than the control range CAA sandwiched between the high response advance angle limit position HRAL and the high response delay angle limit position HRRL as the high response control range HRA. In the vicinity of the mechanical stopper outside the high response control range HRA, the actual phase angle RA is made closer to the target phase angle TA at a slower response speed than the phase angle region in the high response control range HRA. This suppresses overshoot and prevents breakage of the stopper.
That is, when the phase angle is far from the mechanical stopper which is the central region of the variable range VAA, the actual phase angle RA approaches the target phase angle TA with a sufficiently fast response speed, and when the phase angle is close to the mechanical stopper, By making the response speed at which the angle RA approaches the target phase angle TA slower, the overshoot in which the actual phase angle RA changes beyond the target phase angle TA is suppressed, and the actual phase angle RA is greater than the advance side control limiter ACL. Further, it is possible to prevent the actual phase angle RA from changing to the retard angle side with respect to the retard side control limiter RCL, thereby suppressing damage to the stopper due to the stopper collision.

  Here, in the case of the stopper collision, when the actual phase angle RA is changed in the direction approaching the stopper within the phase angle range outside the high response control range HRA, the advance side control limiter ACL (maximum advance angle position AL) is described in detail. ) And the high response advance limit position HRAL, when the actual phase angle RA is advanced toward the maximum advance angle AL, the retard side control limiter RCL (maximum retard position RL) and high If it is between the response delay limit position HRLL and the actual phase angle RA is retarded toward the maximum retard angle position RL, there is a possibility that a stopper collision will occur due to overshoot. On the contrary, even if the phase angle range is out of the high response control range HRA, if the actual phase angle RA is changed in the direction away from the stopper, even if an overshoot occurs, the stopper collision does not occur.

Therefore, the soft landing control in which the response speed at which the actual phase angle RA approaches the target phase angle TA is changed more slowly in the phase angle range outside the high response control range HRA and in the direction approaching the stopper position. If the actual phase angle RA is changed in a direction away from the stopper position, even if the phase angle range is outside the high response control range HRA, it is performed in the high response control range HRA. The actual phase angle RA can be changed at the same response speed as in a certain case.
Here, if the control range CAA is made narrower, the occurrence of a stopper collision due to overshoot can be suppressed without performing soft landing control, but the range in which the actual phase angle RA changes (the set range of the target phase angle TA) is By narrowing, the performance improvement of the internal combustion engine 101 by changing the valve timing cannot be sufficiently obtained.

On the other hand, if the response speed of the phase angle is changed within the control range CAA as described above, the control range CAA can be made as wide as possible while suppressing occurrence of a stopper collision due to overshoot. By sufficiently changing the valve timing, the performance of the internal combustion engine 101 can be sufficiently improved.
For example, by expanding the control range CAA to the advance side, the intake response can be improved by opening the intake valve 105 quickly, and the start acceleration performance can be improved by the advance angle control during start acceleration. Further, by expanding the control range CAA to the retarded angle side, the fuel consumption performance can be improved by the slow closing of the intake valve 105 during constant low speed traveling or deceleration.

In the following, an example of soft landing control by the electronic control unit 201 is shown.
The flowchart of FIG. 6 shows the setting process of the target phase angle TA by the electronic control device 201, and the routine shown in the flowchart of FIG. 6 is repeatedly executed by the electronic control device 201 every predetermined time.
In step S501, the electronic control unit 201 sets a basic value TAB of the target phase angle TA based on the operating state of the internal combustion engine 101. This basic value TAB is a value within the control range CAA. That is, when the phase angle is expressed by the advance angle from the most retarded position (RL or RCL), RCL <TAB <ACL.

Next, in step S502, the electronic control unit 201 detects whether the basic value TAB set this time is within or outside the high response control range HRA. That is, the electronic control unit 201 detects whether or not HRRL <TAB <HRAL is satisfied when the phase angle is represented by an advance angle from the most retarded position (RL or RCL).
Here, when the basic value TAB is a phase angle within the region of the high response control range HRA (when HRRL <TAB <HRAL is satisfied), the electronic control unit 201 finalizes the basic value TAB as it is in step S503. To a target phase angle TA. As a result, the electronic control unit 201 controls the variable valve timing mechanism 114 (electric motor 12) so that the actual phase angle RA approaches the basic value TAB.

On the other hand, when the basic value TAB is a phase angle outside the region of the high response control range HRA, that is, when HRAL <TAB or TAB <HRRL is satisfied, the electronic control unit 201 determines that the target for soft landing is step S504. The value SLTA is calculated.
The soft landing target value SLTA is a target phase angle for reducing the response speed of the actual phase angle RA to the basic value TAB compared to the case where the basic value TAB is within the high response control range HRA. In step S505, the control device 201 sets the soft landing target value SLTA to the final target phase angle TA.

As a result, the electronic control unit 201 controls the variable valve timing mechanism 114 (electric motor 12) so that the actual phase angle RA approaches the soft landing target value SLTA.
In step S506, the electronic control unit 201 outputs the final target phase angle TA, and the variable valve timing mechanism 114 (the electric motor 12) based on the final target phase angle TA and the actual phase angle RA. Implement the control.

In step S504, the electronic control unit 201 calculates the soft landing target value SLTA so as to follow the change in the basic value TAB with a delay. Accordingly, when the actual phase angle RA is changed so as to follow the basic value TAB, in other words, compared to the case where the final target phase angle TA = the basic value TAB, the basic value TAB of the actual phase angle RA is obtained. The response speed to becomes slower.
That is, in the region at both ends close to the stopper in the control range CAA, the response speed of the actual phase angle RA becomes slow and overshoot that deviates from the control range CAA is suppressed. Stopper collision can be suppressed while widening the range CAA.

FIGS. 7A to 7D illustrate change characteristics of the soft landing target value SLTA that follows the basic value TAB with a delay, and the basic value TAB is within the high response control range HRA. A case where the phase angle is switched to the advance side control limiter ACL (or the retard side control limiter RCL) will be exemplified.
FIG. 7A shows that the soft landing target value SLTA is changed from the initial value INA1, which is an intermediate value between the basic value TAB before switching and the basic value TAB after switching, to the basic value TAB after switching at a constant speed ΔA1. This is an example of gradually changing to the advance side control limiter ACL or the retard side control limiter RCL).
The speed ΔA is the amount of change in the phase angle (advance angle) per unit time, and is an index value indicating the degree of decrease in response speed. That is, the faster the speed ΔA is, the smaller the degree of decrease in the response speed is, and the slower the speed ΔA is, the larger the degree of decrease in the response speed is.

  In FIG. 7B, the initial value INA of the soft landing target value SLTA is farther from the basic value TAB before switching and closer to the basic value TAB after switching than the initial value INA1 shown in FIG. The initial value INA2 that is the phase angle is set, and the soft landing target value SLTA gradually approaches the basic value TAB (advanced-side control limiter ACL or retarded-side control limiter RCL) after switching from the initial value INA2. In this example, the speed is set to ΔA2 that is slower than the change speed ΔA1 in FIG.

Further, FIG. 7C shows that the soft landing target value SLTA is held for the predetermined time Δt at the initial value INA3 that is an intermediate value between the basic value TAB before switching and the basic value TAB after switching. This is an example of gradually approaching at a constant speed ΔA3 toward the later basic value TAB.
Further, FIG. 7D shows that the soft landing target value SLTA gradually changes from the basic value TAB before switching to the basic value TAB after switching (the advance side control limiter ACL or the retard side control limiter RCL). This is an example in which the change speed when the soft landing is made slower as the soft landing target value SLTA approaches the basic value TAB after switching.

In the case of the characteristics shown in FIGS. 7A and 7B, in which the soft landing target value SLTA is gradually approximated from the initial value INA to the basic value TAB after switching, the initial value INA is brought close to the basic value TAB after switching. That is, in other words, in FIG. 7B, the phase angle region in which the response speed is lowered by the soft landing control is smaller than that in FIG. 7A.
However, in the characteristics shown in FIG. 7B, the phase angle when starting to gradually change toward the basic value TAB after switching is close to the basic value TAB after switching. In order to suppress the overshoot in which the phase angle RA changes, the change speed ΔA of the soft landing target value SLTA is set more than in the case of FIG. 7A (when the initial value INA is further away from the stopper). It is necessary to slow down, and the time for the actual phase angle RA to reach the basic value TAB after switching becomes longer.

On the other hand, in the case of the characteristic shown in FIG. 7A where the initial value INA is close to the basic value TAB before switching, the phase angle region in which the response speed decreases due to the soft landing control is increased, but the basic value TAB after switching is increased. Since the phase angle when gradually starting to change is far from the basic value TAB after switching, the change speed ΔA of the soft landing target value SLTA can be made relatively fast while suppressing overshoot. The time for the actual phase angle RA to reach the basic value TAB can be shortened as compared with FIG.
Therefore, as shown in FIGS. 7A and 7B, when the soft landing target value SLTA is brought close to the basic value TAB from the initial value INA at a constant speed, the phase angle region in which the response speed decreases is excessively wide. In addition, the initial value INA and the change speed ΔA are set so that the convergence time with respect to the basic value TAB (target rotation phase TA) does not become excessively long.

Further, in the change characteristic of the soft landing target value SLTA shown in FIG. 7C, the change of the actual phase angle RA is once converged around the initial value INA by holding the initial value INA for a predetermined time Δt. After that, the actual phase angle RA is changed toward the basic value TAB.
For this reason, compared with the characteristic of FIG. 7B, it is possible to sufficiently suppress the occurrence of the stopper collision while shortening the time for the actual phase angle RA to reach the basic value TAB. Thus, the area where the response speed is lowered can be reduced.

The predetermined time Δt is set to, for example, the time required for the actual phase angle RA to reach the vicinity of the initial value INA, or the time required for the actual phase angle RA to converge to the initial value INA. The larger the difference between the basic value TAB and the initial value INA, the longer the time can be.
In the change characteristic of the soft landing target value SLTA shown in FIG. 7D, immediately after the basic value TAB is switched, the actual phase angle RA is changed with good response, and the response becomes closer to the basic value TAB. The characteristic of delaying the speed can be set with a high degree of freedom, and the responsiveness to the basic value TAB and the suppression of overshoot can be achieved at a high level.

In the change characteristic of the soft landing target value SLTA shown in FIG. 7D, the soft landing target value SLTA is changed using the basic value TAB before switching as an initial value. The soft landing target value SLTA can be brought closer to the basic value TAB after the switching while gradually decreasing the change speed ΔA from the initial value INA that is an intermediate value with the basic value TAB after the switching.
In the characteristics shown in FIG. 7C, the soft landing target value SLTA is brought closer to the basic value TAB after switching at a constant speed from the time when the predetermined time Δt has elapsed, but the closer to the basic value TAB after switching. The change rate ΔA can be further reduced.

The flowchart of FIG. 8 shows another example of the setting process of the target phase angle TA by the electronic control device 201, and the routine shown in the flowchart of FIG. 8 is repeatedly executed by the electronic control device 201 every predetermined time. .
In the flowchart of FIG. 8, as illustrated in FIGS. 7A to 7C, an initial value INA that is an intermediate value between the basic value TAB before switching and the basic value TAB after switching is set. In the process of gradually changing the soft landing target value SLTA up to INA and then gradually approaching the soft landing target value SLTA toward the basic value TAB after switching at a constant change rate ΔA, the initial values INA and / or Alternatively, an example of processing for changing the change rate ΔA according to at least one of the change amount of the basic value TAB and the change rate ΔRA of the actual phase angle RA will be described.

In step S601, the electronic control unit 201 sets the basic value TAB of the target phase angle TA as a value within the control range CAA based on the operating state of the internal combustion engine 101.
Next, in step S602, the electronic control unit 201 detects whether the basic value TAB is within or outside the high response control range HRA.

If the basic value TAB is a value within the high response control range HRA, the electronic control unit 201 sets the basic value TAB as it is as the final target phase angle TA in step S603. As a result, the electronic control unit 201 controls the variable valve timing mechanism 114 (electric motor 12) so that the actual phase angle RA approaches the basic value TAB.
On the other hand, if the basic value TAB is a phase angle outside the region of the high response control range HRA, the electronic control unit 201 starts the soft landing control start phase angle (initial value INA) and the target value for soft landing in step S604. A process of variably setting at least one of the SLTA change rate ΔA is performed.

Here, the electronic control unit 201 uses at least one of the initial value INA and the change rate ΔA as the change amount ΔTAB of the basic value TAB (target phase angle according to the engine operating state) and the change rate ΔRA of the actual phase angle RA. It is variably set based on (response speed of the variable valve timing mechanism 114).
The change amount ΔTAB of the basic value TAB is an absolute value of a deviation between the basic value TAB before switching and the basic value TAB after switching. When the amount of change ΔTAB is large, the actual phase angle RA needs to be moved greatly, the initial value of the control deviation (error) is large, and the variable valve timing mechanism 114 (electric motor 12) is controlled based on the control deviation. Overshoot is likely to occur.

Therefore, as illustrated in FIG. 9, the electronic control unit 201 sets the phase angle farther from the stopper position to the initial value INA as the change amount ΔTAB of the basic value TAB is larger, and from the phase angle farther from the stopper position. Start soft landing control.
On the contrary, when the change amount ΔTAB of the basic value TAB is small, the initial value of the control deviation (error) is small, and overshoot occurs when the variable valve timing mechanism 114 (electric motor 12) is controlled based on the control deviation. As illustrated in FIG. 9, the electronic control unit 201 sets the phase angle closer to the stopper position to the initial value INA than when the change amount ΔTAB is large, and performs soft landing from the phase angle close to the stopper position. Start control.

  For example, even when the basic value TAB after switching is the same advance side control limiter ACL, the more the basic value before switching is on the retard side, the further away from the advance side control limiter ACL in the retard direction. The initial position INA is set to the initial value INA, the soft landing target value SLTA is changed stepwise to the initial value INA, and then the soft landing target value SLTA is gradually changed from the initial value INA to the basic value TAB.

As described above, since the overshoot is more likely to occur as the change amount ΔTAB of the basic value TAB is larger, the electronic control device 201 increases the change amount ΔTAB of the basic value TAB as illustrated in FIG. The soft landing target value SLTA change rate ΔA is made slower, the soft landing target value SLTA response delay with respect to the basic value TAB is made larger, and conversely, the smaller the basic value TAB change amount ΔTAB is, the soft landing is made. The target value SLTA change rate ΔA is made faster, and the response delay of the soft landing target value SLTA with respect to the basic value TAB is made smaller.
As described above, if at least one of the initial value INA and the change speed ΔA is changed in accordance with the change amount ΔTAB of the basic value TAB, the response is as fast as possible while suppressing the occurrence of the stopper collision due to the overshoot. Thus, the soft landing target value SLTA (actual phase angle RA) can be changed to follow the basic value TAB.

Further, the change rate ΔRA of the actual phase angle RA includes the actual phase angle RA when the basic value TAB falls outside the region of the high response control range HRA, and the actual phase angle of the previous time (when the flowchart of FIG. 8 was previously executed). It can be obtained as a difference from RA, and is a transition speed from the inside of the high response control range HRA to the outside of the area, in other words, a change speed of the actual phase angle RA toward the stopper position.
When the change speed (response speed) ΔRA of the actual phase angle RA is fast, overshooting is more likely to occur than when the change rate ΔTAB of the basic value TAB is the same as compared with the slow speed.

Therefore, as illustrated in FIG. 11, the electronic control unit 201 sets the phase angle farther from the stopper position to the initial value INA as the change speed ΔRA of the actual phase angle RA is faster, and the phase angle farther from the stopper position. The control to reduce the response speed (soft landing control) is started.
For example, even when the basic value TAB after switching is the same advance angle side control limiter ACL, the change rate ΔRA of the actual phase angle RA when the basic value TAB is switched to the advance angle side control limiter ACL is higher. The position on the more retarded side from the advance side control limiter ACL is set to the initial value INA, the soft landing target value SLTA is changed stepwise to the initial value INA, and then the soft landing target value SLTA is set to the initial value. The value is gradually changed from INA to the basic value TAB.

In addition, as illustrated in FIG. 12, the electronic control unit 201 further decreases the change speed ΔA of the soft landing target value SLTA as the change speed ΔRA of the actual phase angle RA increases, and performs soft landing for the basic value TAB. The response delay of the target value SLTA is further increased, and conversely, the slower the change speed ΔRA of the actual phase angle RA, the faster the change speed ΔSLTA of the soft landing target value SLTA, and the soft landing target value with respect to the basic value TAB SLTA response delay is made smaller.
As described above, if at least one of the initial value INA and the change speed ΔA is changed in accordance with the change speed ΔRA of the actual phase angle RA, the occurrence of a stopper collision due to overshoot is suppressed and the speed is as fast as possible. In response, the soft landing target value SLTA (actual phase angle RA) can be changed to follow the basic value TAB.

Here, when the initial value INA is variably set based on both the change amount ΔTAB of the basic value TAB and the change speed ΔRA of the actual phase angle RA, the change amount ΔTAB of the basic value TAB is small and the actual phase angle When the RA change rate ΔRA is slow, the initial value INA is brought closest to the stopper position, and when the basic value TAB change amount ΔTAB is large and the actual phase angle RA change rate ΔRA is fast, the initial value INA is moved farthest from the stopper position. It will be.
When the change rate ΔA of the soft landing target value SLTA is variably set based on both the change amount ΔTAB of the basic value TAB and the change rate ΔRA of the actual phase angle RA, the change amount ΔTAB of the basic value TAB is set. Is the fastest when the change rate ΔRA of the actual phase angle RA is low and the change rate ΔA is the fastest, and the change rate ΔA is the highest when the change amount ΔTAB of the basic value TAB is large and the change rate ΔRA of the real phase angle RA is fast. Will be late.

As described above, when at least one of the initial value INA and the change rate ΔA is variably set, the electronic control unit 201 sets the soft landing target value SLTA to the initial value INA and then changes the value in step S605. A process of approaching the switched basic value TAB at the speed ΔA is performed, and in step S606, the soft landing target value SLTA set in the process is set to the final target phase angle TA.
In step S607, the electronic control unit 201 outputs the final target phase angle TA, and the variable valve timing mechanism 114 (the electric motor 12) based on the final target phase angle TA and the actual phase angle RA. Implement the control.

Note that the predetermined time Δt in the characteristic of FIG. 7C can be variably set based on at least one of the change amount ΔTAB of the basic value TAB and the change rate ΔRA of the actual phase angle RA.
That is, when the change amount ΔTAB of the basic value TAB is large and when the change speed ΔRA of the actual phase angle RA is fast, the predetermined time Δt is lengthened to converge to the initial value INA, and the change of the basic value TAB When the amount ΔTAB is small and when the change rate ΔRA of the actual phase angle RA is slow, the predetermined time Δt is shortened to suppress a decrease in convergence responsiveness to the basic value TAB.

The technical ideas described in the above embodiments can be used in appropriate combination as long as no contradiction arises.
Although the contents of the present invention have been specifically described with reference to preferred embodiments, it is obvious that those skilled in the art can take various modifications based on the basic technical idea and teachings of the present invention. It is.

As a method of reducing the response speed of the relative rotational phase angle, in the above embodiment, the soft landing target value SLTA that follows the target phase angle (basic value TAB) corresponding to the engine operating state is set. Although the control is performed so that the actual phase angle RA approaches the soft landing target value SLTA, the method of reducing the response speed is not limited to the setting of the soft landing target value SLTA, and various known methods can be used as appropriate. Can be adopted.
For example, when the response speed is reduced, the drive voltage of the electric motor 12 is limited to be lower than when the response speed is not reduced, so that the response speed of the relative rotational phase angle can be reduced, and the drive voltage can be increased. As a means for limiting, a means for reducing the control gain when controlling the drive voltage of the variable valve timing mechanism 114 (electric motor 12) according to the deviation between the target phase angle TA and the actual phase angle RA, or the electric motor 12 is used. A means for reducing the indicated value of the drive voltage can be employed.
In addition, as a variable setting process of the initial value INA and the change speed ΔA, the closer the basic value TAB set in the area outside the high response control range HRA is to the stopper position (in other words, the basic value TAB and the maximum advance angle position). By increasing the interval between the initial value INA and the stopper position and / or slowing the change speed ΔA, the decrease in responsiveness is suppressed and the overshoot is suppressed. Stopper collision can be suppressed.

When the change speed ΔA is variably set, even if a stopper collision occurs, the maximum speed that causes an impact within the allowable range is set to the maximum value, and the minimum resolution in detecting the actual phase angle RA is set to the minimum value. It can be variably set within a speed range between the maximum value and the minimum value.
Further, the change characteristic of the soft landing target value SLTA can be changed based on the acceleration of the actual phase angle RA, and the larger the rate of increase in the speed approaching the stopper position, the farther the initial value INA is from the stopper position. Further, the change rate ΔA can be slowed down.

Here, technical ideas other than the claims that can be grasped from the above embodiment will be described together with effects.
(I)
A target value for soft landing that follows the target phase angle corresponding to the operating state of the internal combustion engine is set, and a variable valve timing mechanism is controlled according to the target value for soft landing to respond to the relative rotational phase angle. The control device for a variable valve timing mechanism according to any one of claims 1 to 3, wherein the speed is decreased.
According to the above invention, the soft landing target value changes behind the target phase angle corresponding to the operating state of the internal combustion engine, so that the relative value compared to the case where the variable valve timing mechanism is controlled according to the target phase angle. The response speed of the rotational phase angle is reduced, and overshoot is suppressed.

(B)
The control of the variable valve timing mechanism according to claim 1, wherein when the target phase angle is out of the predetermined phase angle range, the soft landing target value is gradually approached from an initial value toward the target phase angle. apparatus.
According to the above invention, when the target phase angle is out of the predetermined phase angle range and close to the stopper position, the soft landing target value gradually approaches the target phase angle from the initial value, and the soft landing target The response speed of the relative rotational phase angle is reduced by changing the actual phase angle along the value.

(C)
The at least one of the initial value and the change speed of the soft landing target value is changed according to at least one of the change amount of the target phase angle and the change speed of the actual relative rotational phase angle. ) The control device for the variable valve timing mechanism.

According to the above invention, the larger the amount of change in the target phase angle, the easier the overshoot occurs, and the faster the actual relative rotational phase angle change speed (speed approaching the stopper), the more likely the overshoot occurs. By setting the initial value (in other words, the start phase angle of the process for delaying the response speed) to a position further away from the stopper position, it is possible to suppress the occurrence of overshoot, and to increase the change speed of the target value for soft landing. By slowing down, the occurrence of overshoot can be suppressed.
Therefore, the ease of overshoot is determined from at least one of the change amount of the target phase angle and the actual speed of change of the relative rotational phase angle, and the initial value and the software are determined according to the ease of occurrence of the overshoot. By changing at least one of the change speed of the landing target value, it is possible to suppress the arrival (convergence) of the target phase angle from being excessively delayed while suppressing the stopper collision due to the overshoot.

(D)
The variable valve timing mechanism is
A driving rotating body to which rotational force is transmitted from the crankshaft;
An electric motor that rotates integrally with the drive rotator and is fed via a brush;
A phase change mechanism that changes a relative rotation phase angle of the camshaft with respect to the crankshaft by rotating an output shaft of the electric motor relative to the drive rotor;
A stopper for regulating the relative rotational position of the advance side and the retard side of the camshaft;
The control apparatus of the variable valve timing mechanism as described in any one of Claim 1 to 3 containing this.
According to the above invention, in the electric variable valve timing mechanism that changes the relative rotation phase angle by the rotation of the output shaft of the electric motor, the control range of the relative rotation phase angle can be expanded while suppressing the stopper collision.

  DESCRIPTION OF SYMBOLS 1d ... Stopper convex part, 2b ... Stopper groove, 12 ... Electric motor (electric actuator), 101 ... Internal combustion engine, 105 ... Intake valve, 109 ... Crankshaft, 114 ... Variable valve timing mechanism, 115a ... Intake camshaft, 201 ... ECU

Claims (3)

A control device for a variable valve timing mechanism that changes a relative rotational phase angle of a camshaft with respect to a crankshaft of an internal combustion engine within a variable range regulated by a stopper,
Response speed lowering means for lowering the response speed of the relative rotational phase angle when the relative rotational phase angle deviates from the predetermined phase angle range included in the variable range compared to when the relative rotational phase angle is within the predetermined phase angle range. With
The response speed reducing means controls the variable valve timing mechanism that changes at least one of a phase angle for starting the reduction of the response speed and a reduction degree of the response speed in accordance with a change state of the relative rotational phase angle. apparatus. 2. The variable valve timing according to claim 1, wherein the response speed reduction means reduces the response speed of the relative rotational phase angle in a direction approaching a phase angle regulated by the stopper in a range outside the predetermined phase angle range. Control device for the mechanism. The response speed lowering means determines at least one of a phase angle for starting a decrease in the response speed and a decrease degree of the response speed, a change amount of a target value of the relative rotational phase angle, and an actual value of the relative rotational phase angle. The control device for a variable valve timing mechanism according to claim 1, wherein the control device changes in accordance with at least one of the change speed of the variable valve timing mechanism.