JP6459886B2 - Electric valve timing control device - Google Patents

Description

  The present invention relates to an electric valve timing control device for controlling valve timing of an internal combustion engine.

  2. Description of the Related Art In recent years, electric valve timing control devices that control valve timing using an electric motor that rotates by energization have been widely installed in internal combustion engines.

  For example, the electric valve timing control devices disclosed in Patent Documents 1 and 2 adjust the rotation phase of the cam shaft in the internal combustion engine with respect to the crankshaft by the phase adjustment unit according to the rotation state of the electric motor. In general, it is possible to accurately control the valve timing determined by the rotational phase by using an electric motor that is excellent in responsiveness and low temperature driving performance.

  Now, the electric valve timing control device disclosed in Patent Document 1 is based on the rotation state of the electric motor detected by the motor sensor as the internal combustion engine stops, and the energization control to the motor is executed. The rotational phase is adjusted to the starting phase.

  On the other hand, the electric valve timing control device disclosed in Patent Document 2 has a stopper structure that mechanically restricts the rotational phase at the phase end. Therefore, in order to mitigate the impact generated when the rotational phase is restricted in the stopper structure, the energization control to the electric motor is executed in stages.

JP 2009-13975 A JP-A-2015-132178

  However, in the electric valve timing control device disclosed in Patent Document 1, when the electric motor receives a large external force exceeding the magnetic holding torque due to vibration or the like between the time when the internal combustion engine is stopped and the next time it is started. There is a concern that the electric motor rotates to cause a rotational phase shift. In this case, if a stopper structure as disclosed in Patent Document 2 is provided in the phase adjustment unit, a problem occurs when the internal combustion engine is started. Here, the problem is that the energization control to the electric motor is executed without knowing the shift of the rotation phase, so that the rotation phase reaches the phase end by mistake and a large impact is generated in the stopper structure. . Such a large impact is desirably suppressed because it leads to a decrease in durability of the phase adjustment unit and the internal combustion engine.

  The present invention has been made in view of the above-described problems, and an object thereof is to provide an electric valve timing control device that ensures the durability of a phase adjustment unit and an internal combustion engine.

  The technical means of the invention for achieving the object will be described below. The reference numerals in parentheses described in the claims and in this section disclosing the technical means of the invention indicate the correspondence with the specific means described in the embodiment described in detail later. It is not intended to limit the technical scope of the invention.

The first invention disclosed in order to solve the above-mentioned problem is
In the electric valve timing control device (1) for controlling the valve timing of the internal combustion engine,
An electric motor (4) that rotates when energized;
A motor sensor (5) for detecting a rotation state which is a rotation angle of the electric motor;
A phase adjusting unit (7) for adjusting a rotational phase of a camshaft relative to a crankshaft in an internal combustion engine according to a relative speed difference with respect to a camshaft of an electric motor, and a stopper structure for mechanically regulating the rotational phase at a phase end A phase adjustment unit having (76);
An energization control unit (6) for performing energization control to the electric motor based on the rotational phase,
The energization control unit that switches to the start mode (Ma) that starts when the internal combustion engine starts after the sleep mode (Ms) that sleeps when the internal combustion engine stops is,
While defining the rotational state that will be detected by the motor sensor according to the transition to the sleep mode, the previous state (Rs),
The rotational state that will be detected by the motor sensor according to the transition to the boot mode, defining the subsequent state (Ra),
In the start-up mode when it is determined that the front state and the rear state are different from each other, the energization control is started so as to limit the change speed of the rotation phase to less than the maximum change speed (Vem).

In addition, the second invention disclosed in order to solve the above-described problem is
In the electric valve timing control device (1) for controlling the valve timing of the internal combustion engine,
An electric motor (4) that rotates when energized;
A motor sensor (5) for detecting a rotation state which is a rotation angle of the electric motor;
A phase adjusting unit (7) for adjusting a rotational phase of a camshaft relative to a crankshaft in an internal combustion engine according to a relative speed difference with respect to a camshaft of an electric motor, and a stopper structure for mechanically regulating the rotational phase at a phase end A phase adjustment unit having (76);
An energization control unit (2006) for performing energization control to the electric motor based on the rotation phase,
The energization control unit that switches to the start mode (Ma) that starts when the internal combustion engine starts after the sleep mode (Ms) that sleeps when the internal combustion engine stops is,
While defining the rotational state that will be detected by the motor sensor according to the transition to the sleep mode, the previous state (Rs),
The rotational state that will be detected by the motor sensor according to the transition to the boot mode, defining the subsequent state (Ra),
In the start-up mode when it is determined that the front state and the rear state are different from each other, the start of energization control is delayed until the rotation phase can be calculated.

The energization control unit according to the first and second inventions switches to a start mode that starts when the internal combustion engine starts after a sleep mode that sleeps when the internal combustion engine stops. Here, the rotation state, which is the rotation angle of the electric motor detected by the motor sensor according to the transition to the sleep mode, is defined as the previous state, and is detected by the motor sensor according to the transition to the start mode. A rotation state that is a rotation angle of the electric motor is defined as a rear state.

  Under such a definition, the energization control unit according to the first invention starts energization control so as to limit the change speed of the rotational phase in the start-up mode when it is determined that the front state and the rear state are different. According to this, when the electric motor rotates and the rotational phase shifts between the time when the internal combustion engine is stopped and the next is started, the change speed of the rotational phase is the highest because the previous state and the rear state are different. It can be limited to less than the rate of change. Therefore, even if the rotational phase reaches the phase end by mistake, the arrival speed is limited to less than the maximum change speed, so that the impact generated in the stopper structure can be mitigated. Therefore, it is possible to ensure the durability of the phase adjustment unit and the internal combustion engine.

  On the other hand, under the above-described definition, the energization control unit according to the second invention starts energization control until the rotation phase can be calculated in the start mode when it is determined that the front state and the rear state are different. Delay. According to this, when the electric motor rotates and the rotational phase shifts between the time when the internal combustion engine is stopped and the next is started, the rotational state accurately calculated is the difference between the previous state and the rear state. The energization control can be started based on the above. Therefore, the impact generated in the stopper structure can be mitigated by accurate energization control that prevents the rotational phase from erroneously reaching the phase end. Therefore, it is possible to ensure the durability of the phase adjustment unit and the internal combustion engine.

It is a block diagram which shows the valve timing control apparatus by 1st embodiment, Comprising: It is the II sectional view taken on the line of FIG. It is the II-II sectional view taken on the line of FIG. FIG. 3 is a cross-sectional view taken along line III-III in FIG. 1. It is a block diagram which shows a drive circuit in detail among the electricity supply control units by 1st embodiment. It is a block diagram which shows a control circuit in detail among the electricity supply control units by 1st embodiment. It is a schematic diagram which shows the detection characteristic of the motor sensor by 1st embodiment. It is a graph which shows the control characteristic of the electricity supply control unit by 1st embodiment. It is a graph which shows the control characteristic of the electricity supply control unit by 1st embodiment. It is a flowchart which shows the sleep flow by the electricity supply control unit by 1st embodiment. It is a flowchart which shows the starting flow by the electricity supply control unit of FIG. It is a block diagram which shows a control circuit in detail among the electricity supply control units by 2nd embodiment. It is a graph which shows the control characteristic of the electricity supply control unit by 2nd embodiment. It is a flowchart which shows the starting flow by the electricity supply control unit by 2nd embodiment.

  Hereinafter, a plurality of embodiments of the present invention will be described with reference to the drawings. In addition, the overlapping description may be abbreviate | omitted by attaching | subjecting the same code | symbol to the corresponding component in each embodiment. When only a part of the configuration is described in each embodiment, the configuration of the other embodiment described above can be applied to the other part of the configuration. In addition, not only combinations of configurations explicitly described in the description of each embodiment, but also the configurations of a plurality of embodiments can be partially combined even if they are not explicitly specified unless there is a problem with the combination. .

  As shown in FIG. 1, the valve timing control device 1 according to the first embodiment is installed in a transmission system that transmits crank torque from a crankshaft to a camshaft 2 in an internal combustion engine of a vehicle. Here, the camshaft 2 opens and closes the intake valve among the valves of the internal combustion engine by transmitting the crank torque. Therefore, the apparatus 1 variably controls the valve timing determined by the rotational phase of the camshaft 2 with respect to the crankshaft (hereinafter simply referred to as “rotational phase”) with respect to the intake valve. As shown in FIGS. 1 to 5, the device 1 includes an electric motor 4, a motor sensor 5, an energization control unit 6, and a phase adjustment unit 7.

  As shown in FIG. 1, the electric motor 4 is a brushless motor such as a permanent magnet type synchronous motor. The electric motor 4 includes a motor case 40, a bearing 41, a motor shaft 42, a magnetic rotor 43, and a motor stator 45.

  The motor case 40 is fixed to a fixed node such as a chain case of the internal combustion engine. The motor case 40 is formed in a cylindrical shape and accommodates the other components 41, 42, 43, 45 of the electric motor 4 therein. The pair of bearings 41 respectively support the motor shaft 42 so as to be able to rotate forward and backward. The magnetic rotor 43 is formed in an annular plate shape that protrudes radially outward from the motor shaft 42, and can rotate forward and backward in the circumferential direction. The magnetic rotor 43 has a plurality of rotor magnets 44 so as to be integrally rotatable at positions spaced equidistantly in the forward and reverse rotational directions. The motor stator 45 is formed in an annular plate shape and surrounds the magnetic rotor 43 coaxially from the outside in the radial direction. The motor stator 45 has a plurality of stator cores 46 and a plurality of motor coils 47, respectively. The stator cores 46 are arranged at equal intervals in the forward and reverse rotation directions of the motor shaft 42 and the magnetic rotor 43. Each motor coil 47 is individually wound around the corresponding stator core 46 and is star-connected to each other as shown in FIG.

  As shown in FIG. 4, the motor sensor 5 includes three-phase rotation detection elements SU, SV, SW. Each rotation detection element SU, SV, SW is, for example, a magnetoelectric conversion element such as a Hall element. The rotation detection elements SU, SV, SW are arranged at predetermined intervals in the forward / reverse rotation direction of the motor shaft 42. Each rotation detection element SU, SV, SW senses the magnetic field formed by the sensor magnet 48 that the magnetic rotor 43 has so as to be integrally rotatable. Thereby, each rotation detection element SU, SV, SW outputs a rotation detection signal based on the sensed magnetic field.

  Specifically, each rotation detection element SU, SV, SW is turned on when the north pole of the sensor magnet 48 is located within each sensing range, thereby raising the voltage level of the rotation detection signal to a high level as shown in FIG. Set to H. On the other hand, each rotation detection element SU, SV, SW is turned off when the S pole of the sensor magnet 48 is located within the sensing range, so that the voltage level of the detection signal becomes a low level L as shown in FIG. Detection signals D1, D2, D3, D4, D5, and D6 whose voltage levels are switched at predetermined rotation angles (for example, every 15 degrees) of the motor shaft 42 are detected from the detection signals of the respective rotation detection elements SU, SV, and SW. Make it appear. Therefore, the rotation detection signal of each rotation detection element SU, SV, SW is a signal that jointly represents the rotation state of the motor shaft 42.

  The energization control unit 6 shown in FIGS. 1, 4, and 5 controls energization to each motor coil 47 based on the operation state of the internal combustion engine, the rotation state of the motor shaft 42, and the like. The electric motor 4 energizes each motor coil 47 in sequence by receiving energization controlled by the energization control unit 6. As a result, a magnetic field acting on each rotor magnet 44 is formed, so that the motor shaft 42 rotates counterclockwise or clockwise in FIG. In FIG. 2, the counterclockwise direction is the forward rotation direction of the motor shaft 42, and the clockwise direction is the reverse rotation direction of the motor shaft 42.

  As shown in FIGS. 1 to 3, the phase adjustment unit 7 includes a drive rotator 70, a driven rotator 71, a planet carrier 72, a shaft joint 73, a planetary bearing 74, and a planetary gear 75.

  The drive rotator 70 is formed in a cylindrical shape by screwing a plurality of members on the same axis. The drive rotator 70 accommodates the other components 71 to 75 in the phase adjustment unit 7 therein. The drive rotating body 70 forms a drive side internal gear portion 70a having a tooth tip circle on the inner peripheral side of the root circle. The drive rotator 70 forms a plurality of sprocket teeth 70b that project radially outward from locations that are equally spaced in the circumferential direction. The drive rotator 70 is linked to the crankshaft by spanning a timing chain between the sprocket teeth 70b and the plurality of teeth of the crankshaft. Due to this connection, the drive rotator 70 is transmitted with crank torque from the crankshaft through the timing chain, so that the drive rotator 70 operates in a fixed circumferential direction (that is, the counterclockwise direction in FIG. 2 and the timepiece in FIG. 3). Direction).

  As shown in FIGS. 1 and 3, the driven rotator 71 is formed in a bottomed cylindrical shape, and is fitted coaxially to the radially inner side of the drive rotator 70. The driven rotating body 71 forms a driven side internal gear portion 71a having a tooth tip circle on the inner peripheral side of the root circle. The driven rotor 71 is coaxially connected to the cam shaft 2. With this connection, the driven rotator 71 rotates in a certain circumferential direction (that is, clockwise in FIG. 3) in conjunction with the camshaft 2 while being retarded in the circumferential direction with respect to the drive rotator 70. And relative rotation in the advance direction. Here, the rotation directions of the rotating bodies 70 and 71 and the cam shaft 2 coincide with the positive rotation direction of the motor shaft 42.

  As shown in FIGS. 1 to 3, the planetary carrier 72 is formed in a partially eccentric cylindrical shape, and is coaxially disposed on the radially inner side of the rotating bodies 70 and 71. The planet carrier 72 is connected to the motor shaft 42 via a joint 73. With this connection, the planetary carrier 72 is rotated integrally with the motor shaft 42 in the forward and reverse directions in the circumferential direction, and relatively rotated in the retarded direction and the advanced direction in the circumferential direction with respect to the drive side internal gear portion 70a. It is possible. The planetary carrier 72 forms an eccentric portion 72 a by a cylindrical outer peripheral surface that is eccentric from the rotating bodies 70 and 71 and the motor shaft 42. The eccentric portion 72 a is fitted coaxially with the planetary gear 75 via the planetary bearing 74. The planetary gear 75 that is supported by the eccentric portion 72a by such fitting is capable of planetary movement in accordance with the relative rotation of the planet carrier 72 with respect to the drive-side internal gear portion 70a.

  The planetary gear 75 is formed in a stepped cylindrical shape, and is arranged eccentrically with respect to the rotating bodies 70 and 71 and the motor shaft 42. The planetary gear 75 forms a drive-side external gear portion 75a and a driven-side external gear portion 75b having a tooth tip circle on the outer peripheral side of the root circle. The drive-side external gear portion 75a meshes with the drive-side internal gear portion 70a so as to be capable of planetary movement. The driven side external gear portion 75b meshes with the driven side internal gear portion 71a so as to be capable of planetary movement.

  With the above configuration, the phase adjustment unit 7 adjusts the rotation phase according to the rotation state of the motor shaft 42 in the electric motor 4 that is energized and controlled by the energization control unit 6. Specifically, when the motor shaft 42 rotates forward at the same speed as the cam shaft 2, the planet carrier 72 does not rotate relative to the drive side internal gear portion 70a. As a result, the planetary gear 75 rotates with the rotators 70 and 71 without planetary motion, so that the rotational phase is kept substantially constant. On the other hand, when the motor shaft 42 rotates forward at a lower speed than the cam shaft 2 or reversely rotates with respect to the cam shaft 2, the planetary carrier 72 rotates relative to the driving side internal gear portion 70a in the retard direction. As a result, the planetary gear 75 moves in a planetary motion and the driven rotator 71 rotates relative to the drive rotator 70 in the retarding direction, so that the rotational phase is retarded. On the other hand, when the motor shaft 42 rotates forward at a higher speed than the cam shaft 2, the planet carrier 72 rotates relative to the driving side internal gear portion 70a in the advance direction. As a result, the planetary gear 75 moves in a planetary motion and the driven rotator 71 rotates relative to the drive rotator 70 in the advance angle direction, so that the rotation phase is advanced.

  The phase adjustment unit 7 is further provided with a stopper structure 76 as shown in FIGS. The stopper structure 76 has a stopper groove 77 and a stopper protrusion 78. The stopper groove 77 is formed in a groove shape that is recessed inward in the radial direction in the drive rotator 70. The stopper groove 77 extends in an arc shape in the circumferential direction of the drive rotator 70. An inner end face of the stopper groove 77 in the retard direction forms a most retarded stopper face 77a. On the other hand, the inner end surface of the stopper groove 77 in the advance direction forms the most advanced stopper surface 77b. The stopper protrusion 78 is formed in a fan shape that protrudes radially outward in the driven rotor 71. The stopper projection 78 is inserted into the stopper groove 77 so that it can rotate relative to the groove 77 in the retard direction and the advance direction.

  As shown by a solid line in FIG. 3, the most retarded stopper surface 77 a abuts on a stopper projection 78 that is relatively rotated in the retard direction within the stopper groove 77, thereby retarding the driven rotor 71 with respect to the drive rotor 70. Stop relative rotation in the direction. As a result, the rotational phase is mechanically regulated at the most retarded phase end. On the other hand, as shown by a two-dot chain line in FIG. 3, the most advanced angle stopper surface 77 b abuts against a stopper projection 78 that is relatively rotated in the advance angle direction within the stopper groove 77, thereby causing the driven rotator relative to the drive rotator 70. The relative rotation of 71 in the advance direction is stopped. As a result, the rotational phase is mechanically restricted at the phase end of the most advanced angle.

(Energization control unit)
Next, the energization control unit 6 will be specifically described.

  As shown in FIGS. 1, 4, and 5, the energization control unit 6 includes a drive circuit 60 and a control circuit 66. In the present embodiment, the drive circuit 60 is disposed inside the electric motor 4 and the control circuit 66 is disposed outside the electric motor 4. For example, both the drive circuit 60 and the control circuit 66 are external to the electric motor 4. Or you may arrange | position collectively inside.

  As shown in FIG. 4, the drive circuit 60 includes an inverter circuit unit 62 and a switching drive unit 63. The inverter circuit unit 62 is a so-called three-phase bridge circuit in which three-phase upper switching elements FU, FV, FW and three-phase lower switching elements GU, GV, GW are electrically connected to each other corresponding to each other. is there. Each upper switching element FU, FV, FW and each lower switching element GU, GV, GW are electrically connected to a corresponding motor coil 47. All of the switching elements FU, FV, FW, GU, GV, and GW having such an electrical connection form are field-effect transistors that are driven on and off in this embodiment, but may be other types of switching elements.

  The switching drive unit 63 is an electronic circuit such as a drive IC, for example. The switching drive unit 63 is electrically connected to the control circuit 66, the switching elements FU, FV, FW, GU, GV, and GW, and the rotation detection elements SU, SV, and SW. The switching drive unit 63 drives the switching elements FU, FV, FW, GU, GV, and GW on and off so as to give the motor shaft 42 the target rotational speed represented by the control signal output from the control circuit 66. At this time, the switching drive unit 63 selects each switching element based on the detection patterns D1, D2, D3, D4, D5, and D6 that appear in the rotation detection signals of the rotation detection elements SU, SV, and SW as shown in FIG. Switch on / off of FU, FV, FW, GU, GV, GW. As a result, the actual rotation speed of the motor shaft 42 is controlled toward the target rotation speed by switching the motor coil 47 to be energized. In the following description, the detection patterns D1, D2, D3, D4, D5, and D6 are collectively referred to as a detection pattern D as shown in FIG.

  For such a drive circuit 60, the control circuit 66 controls energization of the electric motor 4 by the drive circuit 60. Therefore, in the following, controlling the energization of the electric motor 4 by the drive circuit 60 by the control circuit 66 will be described as executing the energization control of the motor 4.

  As shown in FIG. 5, the control circuit 66 is an electronic circuit mainly composed of a microcomputer having a processor 67 and a memory 68. Control circuit 66 is electrically connected to a plurality of vehicle electrical components including sensors Scr, Sca, St and switch SWp, and drive circuit 60. Here, the crank rotation sensor Scr is a rotation sensor such as an electromagnetic pickup type. The crank rotation sensor Scr detects the rotation of the crankshaft and outputs a crank angle detection signal representing the rotation angle θcr of the crankshaft. The cam rotation sensor Sca is a rotation sensor such as an electromagnetic pickup type. The cam rotation sensor Sca detects the rotation of the cam shaft 2 and outputs a cam angle detection signal representing the rotation angle θca of the cam shaft 2. The temperature sensor St is, for example, a thermistor dedicated to the device 1 or a vehicle room temperature sensor. The temperature sensor St detects the environmental temperature T of the device 1 and outputs a temperature detection signal representing the detection result. The power switch SWp is, for example, a rotary or push type on / off switch. The power switch SWp is turned on to allow the vehicle occupant to start the internal combustion engine, while the occupant is turned off to stop the internal combustion engine. The power switch SWp outputs a power signal corresponding to those operations. As shown in FIGS. 4 and 5, the drive circuit 60 outputs a rotation detection signal of each rotation detection element SU, SV, SW via itself.

  Based on these various outputs, the control circuit 66 executes energization control (hereinafter simply referred to as “energization control”) to the electric motor 4 by the processor 67. In such energization control, the control circuit 66 executes a specific calculation process. Specifically, in the calculation process, the actual phase Pr is calculated based on the rotation angles θcr and θca represented by the detection signals received from the rotation sensors Scr and Sca. At the same time, in the calculation process, the target phase Pt with respect to the actual phase Pr is calculated based on a signal between the vehicle electrical component including the temperature sensor St. Further, in the calculation process, the target of the motor shaft 42 is determined based on the calculated actual phase Pr and target phase Pt and the detection pattern D represented by the rotation detection signal received from each rotation detection element SU, SV, SW through the drive circuit 60. Calculate the rotation speed. By supplying a control signal representing the target rotation speed calculated in this way from the control circuit 66 to the switching drive unit 63, energization control according to the calculation results of the actual phase Pr and the target phase Pt is realized.

  In addition to such energization control, the control circuit 66 executes injection control for controlling fuel injection of the internal combustion engine and ignition control for controlling ignition of the internal combustion engine based on the phases Pr and Pt calculated as needed. In view of this, the control circuit 66 of the present embodiment employs an engine ECU (that is, Electronic Control Unit), so that engine control including injection control and ignition control (hereinafter simply referred to as “engine control”), and energization control are performed. Are executed by the processor 67. Details will be described below.

  The control circuit 66 shifts to the activation mode Ma by sensing the ON operation of the power switch SWp based on the power signal. In the activation mode Ma, the control circuit 66 first activates itself and the drive circuit 60 together. Next, in the start mode Ma, the control circuit 66 executes energization control and engine control from a cranking period in which the internal combustion engine is cranked and started. Thus, after the internal combustion engine is started, the control circuit 66 continues the energization control and the engine control by executing the operation mode Md until the power switch SWp is turned off.

  Further, the control circuit 66 shifts to the sleep mode Ms by detecting the turning-off operation of the power switch SWp based on the power signal during the operation mode Md. In the sleep mode Ms, the control circuit 66 first continues the energization control until the set time elapses after the internal combustion engine is completely stopped by stopping the engine control. Next, in the sleep mode Ms, when the set time elapses after the internal combustion engine is completely stopped, the control circuit 66 causes itself and the drive circuit 60 to sleep until the power switch SWp is turned on.

  In response to the transition to the sleep mode Ms, the control circuit 66 calculates the actual phase Pr based on the rotation angles θcr and θca represented by the detection signals received from the rotation sensors Scr and Sca. The actual phase Pr calculated in the present embodiment is a rotational phase immediately before the internal combustion engine completely stops in the sleep mode Ms or immediately before the control circuit 66 sleeps. The actual phase Pr calculated in this way is stored in a memory 68 as a phase storage unit including a nonvolatile memory, for example.

  Further, in accordance with the transition to the sleep mode Ms, the control circuit 66 defines the rotation state of the motor shaft 42 detected by the motor sensor 5 as the previous state Rs and acquires it. The pre-state Rs acquired in the present embodiment is a pattern immediately before the control circuit 66 sleeps in the sleep mode Ms among the detection patterns D represented by the rotation detection signals of the rotation detection elements SU, SV, and SW. The previous state Rs acquired in this way is stored in the memory 68 that also functions as a state storage unit.

  Further, the control circuit 66 defines the rotation state of the motor shaft 42 detected by the motor sensor 5 as a rear state Ra and acquires it in accordance with the transition to the activation mode Ma by switching after the sleep mode Ms. The post-state Ra acquired in the present embodiment is a pattern immediately after the control circuit 66 is activated in the activation mode Ma among the detection patterns D represented by the rotation detection signals of the respective rotation detection elements SU, SV, and SW. The acquired state Ra is also stored in the memory 68 as a state storage unit.

  As described above, the control circuit 66 that stores the previous state Rs and the rear state Ra in the memory 68 determines whether or not the states Rs and Ra match each time the mode is shifted to the activation mode Ma. At this time, the determination of the present embodiment is made by comparing the pattern of the previous state Rs and the pattern of the subsequent state Ra in the detection pattern D. As a result, in the start-up mode Ma when it is determined that the front state Rs and the rear state Ra match, the control circuit 66 starts normal control En as energization control together with engine control. On the other hand, when it is determined that the front state Rs and the rear state Ra are different from each other, the control circuit 66 starts fail-safe control Ef as energization control together with engine control.

  First, the normal control En will be described. In the normal control En, instead of calculating the actual phase Pr in the above calculation process, the actual phase Pr stored in the memory 68 is read. At the same time, in the normal control En, the target phase Pt is set to the starting phase according to the environmental temperature T indicated by the temperature detection signal of the temperature sensor St. Here, when the environmental temperature T is equal to or higher than a reference temperature (for example, 40 ° C.), the target phase Pt is set at the most retarded phase end in order to suppress preignition and knocking of the internal combustion engine. On the other hand, when the environmental temperature T is lower than the reference temperature, the target phase Pt is set to an intermediate phase between the most retarded phase end and the most advanced angle phase end in order to improve the starting ignitability of the internal combustion engine. Set.

  Further, in the normal control En, the target rotational speed of the motor shaft 42 is calculated as needed based on the read actual phase Pr, the set target phase Pt, and the detection pattern D acquired as needed after storing the rear state Ra. As a result, when the target phase Pt is at the phase end of the most retarded angle shown in FIG. 7B, the change speed of the same phase Pt is the normal change speed Ven as shown by the one-dot chain line graph in FIG. Is adjusted to less than the normal change speed Ven. On the other hand, when the target phase Pt is the intermediate phase shown in FIG. 8B, the change speed of the phase Pt is continuously adjusted to the normal change speed Ven as shown by a one-dot chain line graph in FIG. Is done. Here, the normal change speed Ven is variably adjusted in accordance with the difference between the read actual phase Pr and the set target phase Pt within the range of the maximum change speed Vem related to the target phase Pt. The maximum change speed Vem is the maximum value of the change speed given to the target phase Pt by the device 1.

  Such normal control En is executed together with engine control until the actual phase Pr can be calculated based on the rotation angles θcr and θca in the start-up mode Ma. Further, when the actual phase Pr can be calculated in the startup mode Ma, the energization control based on the calculation result is executed together with the engine control instead of the normal control En. Therefore, in the internal combustion engine, at least during the cranking period, the start-up mode Ma and the normal control En are continuously executed.

  Next, the fail safe control Ef will be described. The fail safe control Ef is the same as the normal control En except that the speed of change is adjusted with respect to the target phase Pt. That is, as in the case of the normal control En, the target rotational speed is calculated at any time, and as a result, when the target phase Pt is the most retarded phase end shown in FIG. As indicated by a solid line graph in a), the temperature is temporarily limited to a predetermined limit change speed Vel and then adjusted to be less than the limit change speed Vel. On the other hand, when the target phase Pt is the intermediate phase shown in FIG. 8B, the change speed of the same phase Pt is continuously limited to the limit change speed Vel as shown by the solid line graph in FIG. The Here, the limit change speed Vel is adjusted to be less than the maximum change speed Vem of the target phase Pt and less than the normal change speed Ven according to the difference between the phases Pr and Pt.

(Sleep flow)
Hereinafter, the sleep flow realized by the control circuit 66 by executing the program stored in the memory 68 by the processor 67 will be described with reference to FIG. This sleep flow is executed when the internal combustion engine is stopped by turning off the power switch SWp during the operation mode Md.

  In S101, the operation mode Md is shifted to the sleep mode Ms. In subsequent S102, it is determined whether the set time has elapsed since the internal combustion engine was completely stopped by stopping the engine control while continuing the energization control. As a result, while a negative determination is made, S102 is repeatedly executed, and when an affirmative determination is made, the process proceeds to S103.

  In S103, the actual phase Pr calculated based on the rotation angles θcr and θca in accordance with the transition to the sleep mode Ms is stored in the memory 68. In subsequent S104, the pattern of the previous state Rs detected by the motor sensor 5 in response to the transition to the sleep mode Ms in the detection pattern D is stored in the memory 68. In further subsequent S105, the control circuit 66 and the drive circuit 60 are caused to sleep, and this sleep flow is terminated. As a result, the sleep mode Ms in which the control circuit 66 and the drive circuit 60 sleep is maintained until a startup flow described later is executed.

(Startup flow)
Hereinafter, a startup flow realized by the control circuit 66 by executing a program stored in the memory 68 by the processor 67 will be described with reference to FIG. This activation flow is executed as the internal combustion engine is started by turning on the power switch SWp during the sleep mode Ms.

  In S201, the sleep mode Ms is shifted to the activation mode Ma. In subsequent S202, the pattern of the post-state Ra detected by the motor sensor 5 in accordance with the transition to the activation mode Ma in the detection pattern D is stored in the memory 68. In the subsequent S203, the latest previous state Rs and the latest rear state Ra stored in the memory 68 are read, and it is determined whether or not these states Rs and Ra match. As a result, when a positive determination is made, the process proceeds to S204, whereas when a negative determination is made, the process proceeds to S207.

  In S204 when the front state Rs matches the rear state Ra, normal control En as energization control is executed together with engine control. As a result, when the calculated target phase Pt reaches the most retarded phase end, the change speed of the target phase Pt is once adjusted to the normal change speed Ven and then adjusted to be less than the normal change speed Ven. On the other hand, when the calculated target phase Pt becomes an intermediate phase, the change speed of the target phase Pt is continuously adjusted to the normal change speed Ven.

  In S205 following S204, it is determined whether or not the actual phase Pr can be calculated based on the rotation angles θcr and θca. As a result, while a negative determination is made, returning to S204 is repeatedly executed, and when an affirmative determination is made, the process proceeds to S206. In S206, the actual phase Pr is calculated based on the rotation angles θcr and θca, and energization control based on the calculation result is executed. When the activation mode Ma is completed as described above, the activation flow is terminated and the operation mode Md is entered.

  On the other hand, in S207 when the front state Rs and the rear state Ra are different, fail-safe control Ef as energization control is executed together with engine control. As a result, when the calculated target phase Pt reaches the most retarded phase end, the change speed of the target phase Pt is once limited to the limit change speed Vel and then adjusted to be less than the limit change speed Vel. On the other hand, when the calculated target phase Pt becomes an intermediate phase, the change speed of the target phase Pt is continuously limited to the limit change speed Vel.

  In S208 following S207, it is determined whether or not the actual phase Pr can be calculated based on the rotation angles θcr and θca. As a result, while a negative determination is made, the process returns to S207 and is repeatedly executed, and when an affirmative determination is made, the process proceeds to S209. In S209, the actual phase Pr is calculated based on the rotation angles θcr, θca, and energization control based on the calculation result is executed. When the activation mode Ma is completed as described above, the activation flow is terminated and the operation mode Md is entered.

(Function and effect)
The effects of the first embodiment described above will be described below.

  The energization control unit 6 according to the first embodiment switches from the sleep mode Ms that sleeps when the internal combustion engine is stopped, to the start mode Ma that starts when the internal combustion engine starts. Here, the rotation state of the electric motor 4 detected by the motor sensor 5 in response to the transition to the sleep mode Ms is defined as the previous state Rs, while detected by the motor sensor 5 in response to the transition to the activation mode Ma. The rotation state of the electric motor 4 is defined as a rear state Ra.

  Under such a definition, the energization control unit 6 according to the first embodiment energizes so as to limit the change speed of the target phase Pt in the start-up mode Ma when it is determined that the front state Rs and the rear state Ra are different. Control (that is, fail-safe control Ef) is started. According to this, when the electric motor 4 rotates and the actual phase Pr shifts between the time when the internal combustion engine is stopped and the next is started, the change speed of the target phase Pt is changed because the states Rs and Ra are different. It can be limited to less than the maximum rate of change Vem. Therefore, even if the actual phase Pr reaches one of the phase ends by mistake, the arrival speed is limited to less than the maximum change speed Vem, so that the impact generated in the stopper structure 76 can be mitigated. Therefore, it is possible to ensure the durability of the phase adjustment unit 7 and the internal combustion engine.

  Here, in particular, the energization control unit 6 according to the first embodiment performs energization control in a mode in which the actual phase Pr is adjusted to the most retarded phase end as the activation mode Ma when it is determined that the states Rs and Ra are different from each other ( That is, the change rate of the target phase Pt is limited to the limit change rate Vel by the fail safe control Ef), and then adjusted to be less than the limit change rate Vel. As a result, as shown in FIGS. 7 and 8, the actual phase Pr changes at the limit change speed Vel that does not erroneously reach the phase end of the most retarded angle within the range below the maximum change speed Vem, and then the limit change. The phase edge of the most retarded angle can be reached at a changing speed lower than the speed Vel. Therefore, it is possible to mitigate the impact generated in the stopper structure 76 while rapidly changing the actual phase Pr to the most retarded phase end as the starting phase. Therefore, it is possible to ensure the durability of the phase adjustment unit 7 and the internal combustion engine while quickly ensuring the startability of the internal combustion engine by adjusting the actual phase Pr to the start phase.

  In particular, the energization control unit 6 according to the first embodiment starts the energization control (that is, normal control En) in the startup mode Ma when it is determined that the states Rs and Ra match, thereby changing the target phase Pt. Adjust the speed to normal change speed Ven. According to this, when the electric motor 4 does not substantially rotate and the actual phase Pr is maintained until the internal combustion engine is stopped and then started, the state Rs and the state Ra coincide with each other. , 8, the actual phase Pr can change at a fast normal change speed Ven before the limit. Therefore, it is particularly effective for quickly ensuring the startability of the internal combustion engine by adjusting the actual phase Pr to the start phase.

  On the other hand, in the activation mode Ma when it is determined that the states Rs and Ra are different from each other, the energization control unit 6 according to the first embodiment starts energization control (that is, fail-safe control Ef), so that the target phase Pt is set. Limit the rate of change. According to this, when the electric motor 4 rotates and the actual phase Pr shifts between the time when the internal combustion engine is stopped and the next is started, the states Rs and Ra are different from each other, as shown in FIGS. In addition, the actual phase Pr can change at a limit change speed Vel that is less than the maximum change speed Vem and less than the normal change speed Ven. Therefore, it is particularly effective in securing the durability of the phase adjustment unit 7 and the internal combustion engine by the impact relaxation in the stopper structure 76.

(Second embodiment)
The second embodiment of the present invention is a modification of the first embodiment.

  As shown in FIG. 11, the control circuit 2066 of the energization control unit 2006 according to the second embodiment executes cranking control for the internal combustion engine as engine control in addition to injection control and ignition control. This cranking control controls cranking for starting the internal combustion engine by the starter motor 2003 in the vehicle. Therefore, the control circuit 2066 is electrically connected to the starter motor 2003.

  Such a control circuit 2066 starts the engine control including the normal control Cn as the cranking control in the activation mode Ma when it is determined that the front state Rs and the rear state Ra match. Specifically, in the normal control Cn, as shown in FIG. 12, the cranking rotational speed is adjusted to a predetermined normal rotational speed Vcn (for example, 300 to 400 rpm) necessary for starting the internal combustion engine. At this time, in normal control En started as energization control, processing similar to that in the first embodiment is executed. As a result, in the starting mode Ma, the normal control En is started based on the actual phase Pr stored in the memory 68 before the actual phase Pr can be calculated based on the rotation angles θcr and θca shown in FIG. It becomes.

  On the other hand, when it is determined that the front state Rs and the rear state Ra are different from each other, the control circuit 2066 starts engine control including fail-safe control Cf as cranking control. Specifically, in the fail-safe control Cf, the cranking rotational speed is set higher than the normal rotational speed Vcn as shown in FIG. 12 within a range where the startability of the internal combustion engine can be ensured (for example, 500 rpm). At this time, the fail safe control Ef started as the energization control in the first embodiment is not started in the second embodiment. As a result, in the start-up mode Ma, the start of energization control is delayed until the actual phase Pr can be calculated based on the rotation angles θcr and θca shown in FIG. That is, the energization control in the startup mode Ma is started based on the calculation result after waiting for the calculation of the actual phase Pr based on the rotation angles θcr and θca. The energization control after waiting for the calculation of the actual phase Pr is executed in the same manner as the normal control En except that it is based on the calculation result instead of based on the actual phase Pr read from the memory 68. Thus, it is possible to ensure the starting phase.

  A startup flow of the second embodiment realized by such a control circuit 2066 will be described with reference to FIG. In the startup flow of the second embodiment, engine control including normal control Cn as cranking control is executed in S2204 instead of S204 of the first embodiment. As a result, the cranking rotation speed is adjusted to the normal rotation speed Vcn. At this time, in S2204, by executing normal control En as energization control, the changing speed of the same phase Pt is adjusted according to the calculation result of the target phase Pt.

  In the startup flow of the second embodiment, engine control including fail-safe control Cf as cranking control is executed in S2207 instead of S207 of the first embodiment. As a result, the cranking rotation speed is increased from the normal rotation speed Vcn. At this time, in S2207, the start of energization control is delayed. As a result, S208 and S209 subsequent to S2207 are executed, and the energization control based on the calculation result is started after waiting for the actual phase Pr to be calculated.

(Function and effect)
The effects of the second embodiment described above will be described below.

  According to the second embodiment, under the definition of the states Rs and Ra as in the first embodiment, the energization control unit 2006 determines the actual phase Pr in the start-up mode Ma when it is determined that the states Rs and Ra are different from each other. The start of energization control is delayed until it can be calculated. According to this, when the electric motor 4 rotates and the actual phase Pr shifts between the time when the internal combustion engine is stopped and the next is started, the states Rs and Ra are different from each other, so that the accurately calculated actual phase is obtained. The energization control can be started based on Pr. Therefore, the impact generated in the stopper structure 76 can be mitigated by accurate energization control that prevents the actual phase Pr from erroneously reaching one of the phase ends. Therefore, it is possible to ensure the durability of the phase adjustment unit 7 and the internal combustion engine.

  Here, in particular, the energization control unit 2006 according to the second embodiment has the actual phase Pr stored in the memory 68 before the actual phase Pr can be calculated in the activation mode Ma when it is determined that the states Rs and Ra match. Based on this, energization control (that is, normal control En) is started. According to this, when the electric motor 4 does not substantially rotate and the actual phase Pr is maintained until the internal combustion engine is stopped and started next time, the states Rs and Ra match, so that the sleep mode Ms The energization control can be started based on the accurate actual phase Pr stored in accordance with the transition to step S2.

  On the other hand, in the activation mode Ma when it is determined that the states Rs and Ra are different, the energization control unit 2006 according to the second embodiment waits until the actual phase Pr can be calculated, and then energizes based on the calculation result. Start control. According to this, when the electric motor 4 rotates and the actual phase Pr shifts between the time when the internal combustion engine is stopped and the next is started, the states Rs and Ra are different from each other, so that the accurately calculated actual phase is obtained. The energization control can be started based on Pr.

  As described above, in any case, in the second embodiment, accurate energization control that avoids the actual phase Pr from erroneously reaching the phase end can be started, and the impact generated in the stopper structure 76 can be mitigated. . Therefore, it is possible to increase the reliability of the effect of ensuring the durability of the phase adjustment unit 7 and the internal combustion engine.

  In particular, the energization control unit 2006 according to the second embodiment starts cranking control (that is, normal control Cn) for the internal combustion engine in the starting mode Ma when it is determined that the states Rs and Ra match. The ranking rotation speed is adjusted to the normal rotation speed Vcn. According to this, when the electric motor 4 does not substantially rotate and the actual phase Pr is maintained until the internal combustion engine is stopped and started next time, the states Rs and Ra coincide with each other. The cranking rotation speed can be adjusted to the normal rotation speed Vcn. Therefore, the energization control based on the actual phase Pr stored in the memory 68 can be started immediately with the start of the internal combustion engine. Therefore, it is possible to ensure the durability of the phase adjustment unit 7 and the internal combustion engine while quickly ensuring the startability of the internal combustion engine by adjusting the actual phase Pr to the start phase.

  On the other hand, in the start-up mode Ma when it is determined that the states Rs and Ra are different, the energization control unit 2006 according to the second embodiment starts cranking control (that is, fail-safe control Cf) for the internal combustion engine. Increase the cranking speed. According to this, when the electric motor 4 rotates and the actual phase Pr shifts between the time when the internal combustion engine is stopped and the next is started, the states Rs and Ra are different, so that the cranking rotational speed is normal rotation. It can be increased above the speed Vcn. Therefore, the time until the actual phase Pr is calculated as the internal combustion engine is started can be shortened by the high cranking rotational speed. As a result, the time for delaying the start of energization control based on the calculated actual phase Pr can also be shortened. Accordingly, it is possible to ensure the durability of the phase adjustment unit 7 and the internal combustion engine while suppressing the deterioration of the startability of the internal combustion engine due to the slow adjustment of the actual phase Pr to the start phase.

(Other embodiments)
Although a plurality of embodiments of the present invention have been described above, the present invention is not construed as being limited to these embodiments, and various embodiments and combinations can be made without departing from the scope of the present invention. Can be applied.

  Specifically, in the first modification example with respect to the first and second embodiments, when the target phase Pt is the most retarded phase end, the normal control En that is the same as when the target phase Pt is the intermediate phase is executed. May be. Further, in the second modification with respect to the first embodiment, when the target phase Pt is the most retarded phase end, the same failsafe control Ef as when the target phase Pt is an intermediate phase may be executed. . Furthermore, in the third modification, the normal control En and the fail safe control Ef according to the first or second embodiment may be executed when the target phase Pt is the phase end of the most advanced angle.

  In the fourth modification regarding the first and second embodiments, the normal change speed Ven by the normal control En may be fixed to a value less than the maximum change speed Vem. Here, in the modified example 4 related to the first embodiment, the limit change speed Vel by the fail-safe control Ef is further matched with the fixed normal change speed Ven so as to be limited to a value less than the maximum change speed Vem. Good.

  In the fifth modification with respect to the second embodiment, the normal control En may be executed as the energization control in the same manner as the fail-safe control Ef. Moreover, in the modification 6 regarding 1st embodiment, you may perform fail safe control Cf as cranking control according to 2nd embodiment. Furthermore, in the modified example 7 regarding the second embodiment, the fail safe control Cf as the cranking control may not be executed.

  In the modified example 8, not only the on / off operation of the power switch SWp but also an idle stop vehicle that can start and stop the internal combustion engine not only by the commands of the control circuits 66 and 2066, but any one of the embodiments is appropriately changed and adopted. Also good. Further, in the modified example 9, any of the embodiments may be appropriately changed and employed in a hybrid vehicle that starts and stops the motor generator together with the internal combustion engine. Furthermore, in the modified example 10, any of the embodiments may be appropriately modified and adopted for the electric valve timing control device that controls the valve timing of the exhaust valve among the valves of the internal combustion engine.

1 valve timing control device, 2 cam shaft, 4 electric motor, 5 motor sensor, 6, 2006 energization control unit, 7 phase adjustment unit, 42 motor shaft, 60 drive circuit, 66, 2066 control circuit, 68 memory, 76 stopper structure , 2003 Starter motor, Cf fail-safe control, Cn normal control, D, D1, D2, D3, D4, D5, D6 detection pattern, Ef fail-safe control, En normal control, Ma start-up mode, Ms sleep mode, Pr real phase , Pt target phase, Ra post-state, Rs pre-state, Vcn normal rotation speed, Vel limit change speed, Vem maximum change speed, Ven normal change speed

Claims (6)

In the electric valve timing control device (1) for controlling the valve timing of the internal combustion engine,
An electric motor (4) that rotates when energized;
A motor sensor (5) for detecting a rotation state which is a rotation angle of the electric motor;
In the internal combustion engine, a phase adjustment unit (7) for adjusting a rotational phase of a cam shaft with respect to a crankshaft according to a relative speed difference between the electric motor and the cam shaft, and mechanically adjusting the rotational phase at a phase end A phase adjusting unit having a stopper structure (76) for regulating;
An energization control unit (6) for performing energization control to the electric motor based on the rotational phase,
The energization control unit that switches to a start mode (Ma) that starts with the start of the internal combustion engine after a sleep mode (Ms) that sleeps with the stop of the internal combustion engine,
The Machinery rolling condition prior to being detected by the motor sensor according to shift to the sleep mode, while defining the previous state (Rs),
The Machinery rolling condition prior to being detected by the motor sensor according to the transition to the startup mode and is defined as the rear state (Ra),
Electric valve timing for starting the energization control so as to limit the change speed of the rotational phase to less than the maximum change speed (Vem) in the start-up mode when it is determined that the front state and the rear state are different from each other. Control device. The energization control unit is
In the mode in which the rotation phase is adjusted to the phase end as the start mode when it is determined that the front state and the rear state are different from each other, the change rate of the rotation phase is a limit change rate less than the maximum change rate. The electric valve timing control device according to claim 1, wherein the energization control is performed so as to adjust to less than the limit change speed after limiting to (Vel). The energization control unit is
In the start-up mode when it is determined that the front state and the rear state match, the energization control for adjusting the rotational phase change speed to the normal change speed (Ven) is started,
In the start-up mode when it is determined that the front state and the rear state are different from each other, the energization control is started so as to limit the change speed of the rotation phase to less than the maximum change speed and less than the normal change speed. The electric valve timing control device according to claim 1 or 2. In the electric valve timing control device (1) for controlling the valve timing of the internal combustion engine,
An electric motor (4) that rotates when energized;
A motor sensor (5) for detecting a rotation state which is a rotation angle of the electric motor;
In the internal combustion engine, a phase adjustment unit (7) for adjusting a rotational phase of a cam shaft with respect to a crankshaft according to a relative speed difference between the electric motor and the cam shaft, and mechanically adjusting the rotational phase at a phase end A phase adjusting unit having a stopper structure (76) for regulating;
An energization control unit (2006) for performing energization control on the electric motor based on the rotational phase;
The energization control unit that switches to a start mode (Ma) that starts with the start of the internal combustion engine after a sleep mode (Ms) that sleeps with the stop of the internal combustion engine,
The Machinery rolling condition prior to being detected by the motor sensor according to shift to the sleep mode, while defining the previous state (Rs),
The Machinery rolling condition prior to being detected by the motor sensor according to the transition to the startup mode and is defined as the rear state (Ra),
An electric valve timing control device that delays the start of the energization control until the rotation phase can be calculated in the start-up mode when it is determined that the front state and the rear state are different. The energization control unit is
A phase storage unit (68) for storing the rotational phase in response to the transition to the sleep mode;
In the start-up mode when it is determined that the front state and the rear state coincide with each other, before the rotation phase is calculated, the energization control is started based on the rotation phase stored in the phase storage unit,
5. The energization control is started based on the calculation result after waiting for the rotation phase to be calculated in the start-up mode when it is determined that the front state and the rear state are different from each other. The electric valve timing control device described. The energization control unit is
Cranking control for starting the internal combustion engine is started so that the cranking rotational speed is adjusted to the normal rotational speed (Vcn) in the start-up mode when it is determined that the front state and the rear state match. While
The cranking control is started according to claim 5, wherein the cranking control is started so as to increase the cranking rotational speed higher than the normal rotational speed in the activation mode when it is determined that the front state and the rear state are different from each other. Electric valve timing control device.

Images