JP2004245230A - Step motor control method for auxiliary air regulating valve - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To avoid the generation of bounce back phenomenon with a simple method to accurately correspond the operation pulse and the opening position to each other when initializing in a step motor control method for an auxiliary air regulating valve for operating the step motor to drive the auxiliary air regulating valve to the valve closing limit or the valve opening limit when initializing so that the number of operation pulse of the step motor connected to the auxiliary air regulating valve and the opening position of the auxiliary air regulating valve correspond to each other. <P>SOLUTION: When driving the auxiliary air regulating valve to the valve opening limit or the valve closing limit in the case of carrying out initialization, driving voltage of the step motor is set smaller than the case of carrying the auxiliary air regulating control by controlling opening of the auxiliary air regulating valve. <P>COPYRIGHT: (C)2004,JPO&NCIPI

Description

  According to the present invention, an initialization process is performed in which the number of operation pulses of a step motor connected to an auxiliary air control valve that adjusts an opening degree of a bypass passage that bypasses a throttle valve corresponds to an opening position of the auxiliary air control valve. In this regard, the present invention relates to a step motor control method for an auxiliary air control valve that operates a step motor to drive the auxiliary air control valve to one of a valve closing limit and a valve opening limit.

Such a step motor control method for an auxiliary air control valve is conventionally known, for example, as described in Patent Documents 1 and 2 below.
JP-B-63-42106 Japanese Patent Publication No. 5-543

  In the above-described conventional device, the auxiliary air control valve and the number of operation pulses of the step motor can be easily associated without using a reference position sensor such as a potentiometer or a limit switch. An initialization process of giving a pulse signal of a fixed number of pulses to the step motor so as to drive the valve to the fully closed or fully open position, and resetting the number of operation pulses of the step motor so that the fully closed or fully open position is a reference position, It is executed immediately after the ignition switch is cut off.

  By the way, when the auxiliary air control valve is driven to any one of the valve closing limit and the valve opening limit, a phenomenon in which the number of steps of the step motor jumps due to the magnetic pole structure of the step motor, a so-called bounce back phenomenon, occurs, An air regulating valve may move out of its closing or opening limits.

  This bounce back phenomenon occurs when the step motor is operated to drive the auxiliary air control valve to either the valve closing limit or the valve opening limit, and the rotor rotates in the reverse direction at the time of the specific excitation pole of the step motor. The stabilizing behavior occurs due to the structure of the stepping motor, which occurs when the rotor has a sufficient inertial force at the time of reverse rotation of the rotor and the reverse rotation timing coincides with the drive frequency.

  Even if the initialization process is performed in a state where such a bounce-back phenomenon occurs, the number of operation pulses of the step motor and the opening position of the auxiliary air control valve cannot be correctly associated with each other. Does not disclose any measures to address the bounceback phenomenon. In Patent Document 2, the bounce-back phenomenon is prevented by controlling the excitation pattern and timing of the step motor, but the control is complicated.

  The present invention has been made in view of such circumstances, and when performing an initialization process for associating the number of operation pulses of a step motor with the opening position of the auxiliary air control valve, the bounce-back phenomenon is performed by a simple method. It is an object of the present invention to provide a method of controlling a step motor of an auxiliary air control valve, which can avoid occurrence of the operation pulse and accurately associate the operation pulse and the opening position.

  In order to achieve the above object, according to the present invention, the number of operating pulses of a step motor connected to an auxiliary air control valve for adjusting an opening of a bypass passage bypassing a throttle valve and the auxiliary air control valve are provided. Step motor control of an auxiliary air control valve that operates a step motor so as to drive the auxiliary air control valve to one of a valve closing limit and a valve opening limit when performing an initialization process that corresponds to the opening position of the auxiliary air control valve In the method, when driving the auxiliary air control valve to one of the valve closing limit and the valve opening limit during the execution of the initialization processing, the driving voltage of the step motor is controlled by performing the auxiliary air amount control by adjusting the opening degree of the auxiliary air control valve. According to the second aspect of the present invention, the opening degree of the bypass passage bypassing the throttle valve is reduced. When performing an initialization process for associating the number of operating pulses of the step motor connected to the auxiliary air control valve to be connected with the opening position of the auxiliary air control valve, the auxiliary air control valve is closed at the valve closing limit and the valve opening limit. In the step motor control method for an auxiliary air control valve configured to operate a step motor to drive the auxiliary air control valve to one of a valve closing limit and a valve opening limit during the execution of the initialization process. In this case, the drive frequency and the drive voltage of the step motor are each made smaller than when the auxiliary air amount control is executed by adjusting the opening of the auxiliary air control valve.

  By the way, as a result of the inventor's research on the bounce-back phenomenon, (1) the natural frequency of the operating part including the rotor of the step motor, that is, the weight of the operating part, and (2) the friction when driving the auxiliary air control valve It has been found that the resistance, (3) the driving thrust of the step motor, that is, the driving voltage, and (4) the driving frequency that affects the resonance are factors that cause the bounce-back phenomenon, and (1), (2) Can not be changed due to the configuration of the step motor and the auxiliary air control valve, whereas (3) and (4) can be changed. Therefore, it is possible to prevent a bounce-back phenomenon from occurring by a simple control in which at least the drive voltage of the drive frequency and the drive voltage is made smaller than when the auxiliary air amount control is performed by adjusting the opening of the auxiliary air control valve. Can be. Moreover, when only the driving voltage is reduced, the driving frequency can be kept high, so that the control speed can be increased.When both the driving voltage and the driving frequency are reduced, the bounce-back phenomenon can be prevented. This can be prevented more reliably, and at this time, the drive voltage can be reduced to a value at which the step-out does not occur.

  As described above, according to the first and second aspects of the invention, when the auxiliary air control valve is driven to one of the valve closing limit and the valve opening limit during the execution of the initialization process, the drive voltage and the drive of the step motor are controlled. The bounce-back phenomenon can be prevented by a simple control in which at least the driving voltage of the frequency is made smaller than that at the time of executing the auxiliary air amount control by adjusting the opening of the auxiliary air control valve.

  In particular, according to the first aspect of the present invention, only the drive voltage can be reduced. In this case, the drive frequency can be kept high, so that the control speed can be increased.

  In particular, in the second aspect of the present invention, since both the driving voltage and the driving frequency are reduced, it is possible to more reliably prevent the bounce-back phenomenon from occurring.

  Hereinafter, embodiments of the present invention will be specifically described based on examples and reference examples of the present invention illustrated in the accompanying drawings.

  1 to 7 show a first reference example. FIG. 1 is a schematic sectional view showing the structure of a throttle device, FIG. 2 is a vertical sectional side view of an idle control valve and a step motor, and FIG. FIG. 4 is a graph showing the result of measuring the occurrence of a bounce-back phenomenon due to the drive voltage and the drive frequency, and FIG. 5 is a diagram showing changes in the step motor drive signal and the idle control valve operating position during the initialization process. FIG. 7 is a diagram sequentially illustrating the operation state of the idle control valve and the power transmission means from the fully closed position, and FIG. 7 is a diagram illustrating changes in the actual position and the target position of the idle control valve after initialization.

  First, in FIG. 1, a throttle body 2 is provided at an intermediate portion of an intake passage 1 connecting an air cleaner AC and an engine E. The throttle body 2 has a throttle valve 3 for adjusting an opening degree of the intake passage 1. A bypass passage 4 is provided rotatably and bypasses the throttle valve 3. The bypass passage 4 guides idle intake air when the engine E is idling. An idle control valve V as an auxiliary air control valve for adjusting the opening of the bypass passage 4 is provided with a throttle valve for controlling the idle speed. It is arranged on the body 2.

  Referring also to FIG. 2, the idle control valve V forms a valve hole 5 connected to the upstream side 4 a of the bypass passage 4, and a valve seat 6 provided in the middle of the bypass passage 4, and a downstream of the bypass passage 4. A valve body 7 that can be seated on the valve seat 6 from the side 4b, and the valve body 7 is connected to a step motor M mounted on the throttle body 2 via power transmission means 8.

  The stepping motor M is conventionally known, and its structure will not be described in detail. However, a small gap is provided between the rotor 10 having the permanent magnet 9 on the outer peripheral surface and the outer peripheral surface of the rotor 10. A pair of stators 11 and 12 that are fixedly arranged and are adjacent in the axial direction are provided. The stators 11 and 12 are provided in common in a cylindrical mold portion 13 made of synthetic resin. The rotor 10 is prevented from moving in the axial direction via a ball bearing 14 so as to prevent the rotor 10 from moving in the mold portion 13. It is supported rotatably.

  The power transmission means 8 is formed by screwing a valve shaft 15 having one end fixed to the valve body 7 and the rotor 10 of the step motor M. That is, a male screw 16 provided on the valve shaft 15 is screwed into a screw hole 17 provided coaxially with the rotor 10, and a ridge 18 protruding along the axial direction on the outer surface of the valve shaft 15. Is fitted into the guide groove 19 provided in the mold portion 13, thereby preventing the valve shaft 15 from rotating around the axis. Therefore, the valve shaft 15 operates in the axial direction in accordance with the rotation of the step motor M, whereby the idle control valve V opens and closes. In addition, a coil-shaped return spring 20 is provided between the valve body 7 and the mold portion 13. The spring force of the return spring 20 causes the idle control valve V to move in the valve closing direction, that is, the valve body 7. Is biased in a direction to make the valve seat 6 sit on the valve seat 6.

  Referring again to FIG. 1, the operation of the step motor M is controlled by the control unit C. The control unit C controls the operation of the step motor M by open-loop control until the complete explosion of the engine. After the explosion, the operation of the step motor M is controlled by feedback control so as to reach a target engine speed corresponding to the engine cooling water temperature. Thus, in the open loop control up to the complete combustion of the engine, the control unit C previously associates the opening position of the idle control valve V with the number of operating pulses of the step motor M from the reference position, The target position is determined so that the current position of the idle control valve V determined by the number of operation pulses of the step motor M matches a target position predetermined as an opening required for starting according to the engine operating state (specifically, engine coolant temperature). And a pulse signal having a pulse number corresponding to the difference between the current positions is output to control the operation of the step motor M.

  Incidentally, the initialization process for associating the number of operation pulses of the step motor M with the opening position of the idle control valve V is executed, for example, immediately after the ignition switch is shut off. C controls the operation of the step motor according to the procedure shown in FIG.

  In step S1 of FIG. 3, the number of repetitions N is set to "0". In step S2, it is checked whether or not the number of repetitions N is equal to or more than the set number of "N0". If N <N0, the repetition is performed in step S3. "1" is added to the number of times N, and the number of operating pulses MP of the step motor M is reduced by "1" in step S4, and the process returns to step S2.

  The set number of times “N0” is set to a value equal to or more than the number of operation pulses of the step motor M for driving the idle control valve V from the fully open position to the fully closed position, and the processing from step S1 to step S4. Accordingly, the idle control valve V is driven to the valve closing limit regardless of the position immediately after the ignition switch is shut off. That is, the idle control valve V is driven to the fully closed side until the valve body 7 is abutted against the valve seat 6.

  In step S2, when N ≧ N0, that is, when the idle control valve V is in the fully closed position, in step S5, the number of operating pulses MP of the step motor M is added by “1”, and in step S6, It is determined whether or not the operation pulse number MP has become equal to the predetermined pulse number MP0. If MP <MP0, the process returns to step S5.

  Here, the predetermined number of pulses MP0 is a value sufficient to drive the step motor M so that the rotor 10 in the power transmission means 8 operates more than the backlash in the power transmission means 8, and the steps S5 and S6 As a result, the idle control valve V is driven from the fully closed position to the set position in the valve opening direction.

  In step S7 after the idle control valve V is opened to the set position in this way, the number M of operation pulses of the step motor M is reset to set the set position as a reference position for idle speed control.

  In the next step S8, the number of operation pulses MP of the step motor M is added by "1". In step S9, it is determined whether the number of operation pulses MP has become equal to the predetermined number of pulses MP1, and MP <MP1. Sometimes, the process returns to step S8.

  Therefore, after the reset of the number of operating pulses of the step motor M is completed, the step motor M is operated by the predetermined number of pulses MP1, and the idle control valve V is driven from the reference position in the valve opening direction. To turn off the power and stop the operation of the step motor M.

  By the way, when the step motor M is operated until the operation pulse number MP reaches the set number of times "N0" by the processing of the above-mentioned steps S1 to S4, that is, when the idle control valve V is operated to the valve closing limit, the step motor M At least one of the drive frequency and the drive voltage of M is set to be smaller than when the auxiliary air amount control is performed by adjusting the opening of the idle air control valve V, that is, when the idle air control is performed.

  As a result of the inventor's research on the bounce-back phenomenon, (1) the natural frequency of the operating portion including the rotor 10 of the step motor M, that is, the weight of the operating portion, and (2) the friction when driving the idle control valve V It has been found that the resistance, (3) the driving thrust of the step motor M, that is, the driving voltage, and (4) the driving frequency that affects the resonance are factors that cause the bounce-back phenomenon, and (1), (2) ) Cannot be changed due to the configuration of the step motor M and the idle control valve V. However, (3) and (4) can be changed, and at least one of the drive frequency and the drive voltage is reduced. By changing it, it is possible to prevent the bounce back phenomenon from occurring.

  On the other hand, when the present inventor measured the occurrence of the bounce-back phenomenon by changing the drive voltage and the drive frequency, the result as shown in FIG. 4 was obtained. In FIG. 4, the drive frequency FU at the time of normal idle control is relatively large in order to increase the control speed, but is not too large such that a step-out may occur when the battery voltage drops extremely, for example, It is set to 200 PPS, and it has been found that the bounce-back phenomenon does not occur at a driving frequency lower than the driving frequency FU, for example, 100 PPS. Therefore, when operating the idle control valve V to the valve closing limit in order to perform the initialization process, the step motor M is operated at a driving frequency of 100 PPS which is a lower driving frequency than that in the normal idle control.

In initializing process immediately after such ignition switch blocked, the actuation of the stepping motor M and the idle regulating valve V, is as shown in Figure 5, set in the closing direction from the time t ₁ the engine is stopped the ignition switch is turned OFF By providing the drive signal to the step motor M as many times as the number of pulses of “N0”, the idle control valve V is reliably completely closed at time t ₂ at any time when the ignition switch is shut off. by predetermined pulse number MP0 only the step motor M is actuated in the opening direction, when the idle regulating valve V is driven in the opening direction to a set position from the fully closed position at time t _3, the idle its position The number M of operation pulses of the step motor M is reset so as to be set as a reference position for the rotation speed control. Further, from time t ₃ , the step motor M is operated in the valve opening direction by a predetermined number of pulses MP1. When the idling control valve V is further operated from the reference position in the valve opening direction at time t ₄ , the step motor M Will stop operating.

  Here, the operation of the idle control valve V from the fully closed position and the operation state of the power transmission means 8 at that time are as shown in FIG. 6, and the idle control valve V shown in FIG. Even when the step motor M is operated by the amount including the backlash δ of the power transmission means 8 and the deviation of the excitation pattern of the step motor M from the fully closed state, as shown in FIG. V is in a fully closed state, and thereafter, when the step motor M is further operated to open the idle control valve V to a certain opening, the number of operation pulses of the step motor M is reset as a reference position of the idle control valve V. Will be done.

  Next, the operation of this reference example will be described. Immediately after the ignition switch is cut off, the idle control valve V is driven to the valve closing limit by the operation of the step motor M, and thereafter, the rotor 10 is moved more than the backlash in the power transmission means 8. The idle control valve V is operated in the valve opening direction from the fully closed position to the set position, and the number of operation pulses of the step motor M is reset so as to set the set position as a reference position for idle speed control. M is operated in the valve opening direction by a predetermined number of steps, and the idle control valve V is further opened from the reference position in the valve opening direction.

  After resetting the number of operation pulses of the step motor M by such control processing, the operation of the step motor M to the target position and the actual operation position of the idle control valve V accompanying the operation of the step motor M are determined. Changes as shown in FIG.

  That is, after the initialization, the actual operation position of the idle control valve V is more than the target position by the operation amount ΔA (from the total operation amount of the step motor M at the time of initialization, the backlash δ of the power transmission means 8 and the excitation pattern in the step motor M). ), And the idle control valve V opens and closes without delaying the operation of the step motor M to the target position. Accordingly, when the engine is restarted, the responsiveness can be improved by operating the idle control valve V quickly to the target opening. Moreover, even in the fine adjustment near the fully closed position, the actual operating position does not differ between the valve opening drive and the valve closing drive of the idle control valve V, so that it is possible to accurately control the idle rotation speed, and to realize the actual operating position. Since it is the target position, it is possible to prevent the engine rotational speed from being jerky, to enable stable idle rotational speed control, and to minimize the possibility of engine stall.

  In addition, since the idle control valve V is in the position slightly opened from the fully closed position in the ignition switch cutoff state, there is no risk of icing, and the idle control valve V is further opened and held after the initialization. The idle control valve V can be quickly operated up to the target opening when the engine is restarted, and the startability is further improved.

  After the complete engine explosion, feedback control of the idle speed is performed to achieve the target engine speed according to the engine cooling water temperature, so even if there is a deviation between the target position and the actual operation position, the actual operation at the target position Since the position is corrected, no problem occurs.

  Furthermore, when the idle control valve V is driven to the valve closing limit, at least one of the drive frequency and the drive voltage of the step motor M is reduced, so that the bounce-back phenomenon can be easily prevented.

  In addition, since the drive frequency is reduced among the drive frequency and the drive voltage, the drive voltage may remain at a relatively high value, and the opening degree of the idle control valve V and the operation pulse of the step motor may be reduced due to the decrease in the drive voltage. There is no risk of stepping out of the correspondence of numbers.

  FIG. 8 shows a first embodiment of the present invention. When the idle control valve V is driven to the valve closing limit, the drive frequency of the step motor M is reduced to the drive frequency FU during idle control, and the drive is performed. The voltage is forcibly reduced to a battery voltage of 12 V by a regulator (not shown). Other than this configuration, the present embodiment is the same as the reference example.

  This makes it possible to more reliably prevent the bounce-back phenomenon from occurring. At this time, by setting the lower limit of the drive voltage to the battery voltage, there is no possibility that the step-out occurs.

  FIG. 9 shows the second embodiment. When the idle control valve V is driven to the valve closing limit, the drive voltage of the step motor M is not changed and the drive voltage is not shown up to 12 V which is the battery voltage. The regulator is forcibly reduced.

  By doing so, the bounce-back phenomenon can be prevented while keeping the control speed high since the driving frequency may be kept high.

  FIGS. 10 and 11 show a second reference example. FIG. 10 is a flowchart showing a control procedure when the idle control valve is driven to the valve closing limit. FIG. 11 is a step motor drive signal at the time of the initialization process. It is a figure which shows the change of the control valve operation position and drive voltage.

  First, in FIG. 10, in step S11, the drive voltage V supplied to the step motor M is detected immediately before the step motor M is driven to one of the valve closing limit and the valve opening limit. It is determined whether or not the detected drive voltage V is equal to or lower than the first set voltage V1. If the detected drive voltage V is equal to or lower than the first set voltage V1 (V ≦ V1), the drive frequency is set at step S13 during idle control. When the drive frequency V is determined to be equal to the drive frequency FU and the detected drive voltage V exceeds the first set voltage V1 (V> V1), the drive frequency is set to a drive frequency F1 smaller than the drive frequency FU during idle control in step S14. Determine.

  In step S15, the step motor M is driven at the drive frequency determined in step S13 or S14 for the number of pulses or the set time of the set number "N0" corresponding to the determined drive frequency.

  By the way, in FIG. 4 described above, when the drive voltage exceeds a certain voltage V1 (for example, 14 V), the bounce-back phenomenon does not occur at the drive frequency F1 set to be lower than the drive frequency FU during idle control, for example, 100 PPS. It can be seen that when the drive voltage is equal to or lower than a certain voltage V1, the bounce-back phenomenon does not occur even at a drive frequency equal to the drive frequency FU during normal idle control. Therefore, the voltage V1 is defined as the first set voltage, and the drive frequency when the detected drive voltage V exceeds the first set voltage V1 is set as the drive frequency F1 smaller than the drive frequency during idle control. This makes it possible to prevent the bounce-back phenomenon from occurring by operating the stepping motor M at the optimum driving frequency.

  During such initialization processing, the step motor drive signal and the idle control valve operating position when the detected drive voltage V is equal to or lower than the first set voltage V1 are the same as those in FIG. 11 described above. FIG. 5 shows changes in the step motor drive signal, the idle control valve operating position, and the drive voltage when the voltage exceeds the first set voltage V1.

  12 and 13 show a third reference example of the present invention. FIG. 12 is a flowchart showing a control procedure when the idle control valve is driven to the valve closing limit, and FIG. 13 is a step motor drive during the initialization processing. It is a figure which shows the change of a signal, an idle control valve operation position, and a drive voltage.

  First, in FIG. 12, in step S21, the drive voltage V supplied to the step motor M is detected immediately before the step motor M is moved to the valve closing limit. In step S22, the detected drive voltage V It is determined whether or not the drive voltage V is lower than the set voltage V2. If the detected drive voltage V is lower than the second set voltage V2 (V <V2), the drive frequency is set to be larger than the drive frequency FU during idle control in step S23. When the drive frequency is determined to be the drive frequency F2 and the detected drive voltage V is equal to or higher than the second set voltage V2 (V ≧ V2), in step S24, the drive frequency is set equal to the drive frequency F1 smaller than the drive frequency FU during idle control. Determine.

  In step S25, the step motor M is driven at the drive frequency determined in step S23 or S24 for the number of pulses or the set time of the set number "N0" corresponding to the determined drive frequency.

  By the way, in FIG. 4 described above, in a region not less than the drive frequency F2 (for example, 300 PPS) which is higher than the drive frequency FU during normal idle control, if the drive voltage is lower than a certain voltage V2 (for example, 18 V), It seems that the bounce-back phenomenon did not occur but the bounce-back phenomenon did not occur. When the drive voltage exceeded a certain voltage V2, the bounce-back phenomenon occurred at the drive frequency F1 that was set to be smaller than the drive frequency FU during idle control. I understand that there is no. Therefore, the voltage V2 is defined as the second set voltage, and the drive frequency when the detected drive voltage V is lower than the second set voltage V2 is defined as the drive frequency F2, and the detected drive voltage V is determined as the second set voltage V2. By setting the drive frequency at the above time as the drive frequency F1, the step motor M can be operated at the optimum drive frequency to prevent the bounce-back phenomenon from occurring.

  At the time of such initialization processing, the step motor drive signal and the idle control valve operating position when the detected drive voltage V is equal to or higher than the second set voltage V1 are the same as those in FIG. Are smaller than the second set voltage V1, the changes in the step motor drive signal, the idle control valve operating position, and the drive voltage are as shown in FIG.

  By the way, in the third reference example, when the detected drive voltage V is lower than the second set voltage V1, the drive frequency may be increased to F2 and the drive voltage may be decreased to 12V.

  As described above, the embodiments and the reference examples of the present invention have been described in detail. However, the present invention is not limited to the above embodiments and the reference examples, and various modifications may be made without departing from the present invention described in the claims. It is possible to make design changes.

  For example, in the above-described embodiment, the case where the initialization process is performed immediately after the ignition switch is shut off is described. However, the timing at which the initialization process is performed is not limited to immediately after the ignition switch is shut off, but immediately after the engine stops and after the engine starts. Alternatively, it is possible to perform the initialization processing while the vehicle is running.

  In the above embodiment, the drive frequency FU during idle control is 200 PPS, the drive frequency F1 is 100 PPS, the drive frequency F2 is 300 PPS, the first set voltage V1 is 14 V, and the second set voltage is 18 V. It can be appropriately changed according to the frequency, the set idle control valve V, and the type and weight of the step motor M.

  Further, the present invention is also applicable to a device that drives the idle control valve V to abut in the valve opening direction during the initialization process.

FIG. 2 is a schematic sectional view showing a configuration of a throttle device according to a first reference example. It is a vertical side view of an idle control valve and a step motor. It is a flowchart which shows an initialization processing procedure. 9 is a graph showing a result of measuring occurrence of a bounce-back phenomenon depending on a driving voltage and a driving frequency. FIG. 7 is a diagram illustrating changes in a step motor drive signal and an idle control valve operating position during an initialization process. It is a figure which shows the operation state from the fully closed position of an idle control valve and a power transmission means sequentially. It is a figure showing change of the actual position and the target position of the idle control valve after initialization. FIG. 5 is a diagram illustrating changes in a step motor drive signal, an idle control valve operating position, and a drive voltage during an initialization process according to the first embodiment of the present invention. FIG. 11 is a diagram illustrating changes in a step motor drive signal, an idle control valve operating position, and a drive voltage during an initialization process according to a second embodiment of the present invention. It is a flowchart which shows the control procedure at the time of driving an idle control valve to a valve closing limit in a 2nd reference example. FIG. 7 is a diagram illustrating changes in a step motor drive signal, an idle control valve operating position, and a drive voltage during an initialization process. It is a flowchart which shows the control procedure at the time of driving an idle control valve to the valve closing limit in 3rd reference example. FIG. 7 is a diagram illustrating changes in a step motor drive signal, an idle control valve operating position, and a drive voltage during an initialization process.

Explanation of reference numerals

4 ... Bypass passage M ... Step motor V ... Idle control valve as auxiliary air control valve

Claims (2)

The number of operating pulses of the step motor (M) connected to the auxiliary air control valve (V) for adjusting the opening of the bypass passage (4) bypassing the throttle valve (V); When performing an initialization process for associating the opening position, the auxiliary air control valve (V) is operated to operate the step motor (M) so as to drive the auxiliary air control valve (V) to one of the valve closing limit and the valve opening limit. In the step motor control method for a valve,
In driving the auxiliary air control valve (V) to one of the valve closing limit and the valve opening limit during the execution of the initialization process, the drive voltage of the step motor (M) is adjusted by adjusting the opening degree of the auxiliary air control valve (V). A step motor control method for an auxiliary air control valve, wherein the step motor control method is smaller than when the auxiliary air amount control is executed. The number of operating pulses of the step motor (M) connected to the auxiliary air control valve (V) for adjusting the opening of the bypass passage (4) bypassing the throttle valve (V); When performing an initialization process for associating the opening position, the auxiliary air control valve (V) is operated to operate the step motor (M) so as to drive the auxiliary air control valve (V) to one of the valve closing limit and the valve opening limit. In the step motor control method for a valve,
When the auxiliary air control valve (V) is driven to one of the valve closing limit and the valve opening limit during the execution of the initialization process, the drive frequency and the drive voltage of the step motor (M) are changed to the drive voltage of the auxiliary air control valve (V). A method of controlling a step motor of an auxiliary air control valve, wherein each of the control steps is made smaller than when an auxiliary air amount control is performed by adjusting an opening degree.

Images