This application is based on Japanese Patent Application No. 2004-212218 filed on Jul. 20, 2004, the disclosure of which is incorporated herein reference.
The present invention relates to a valve position controller for controlling the position of a valve based on a rotational position of a magnet rotor of a brushless motor. In particular, the invention relates to a valve position controller for controlling the position of a throttle that corresponds to the rotational angle of a throttle valve by driving the brushless motor in response to the amount that the accelerator is operated by a driver.
There have heretofore been proposed electronically controlled throttle position controllers for electronically controlling the position of a throttle valve by driving a brushless DC motor depending upon the amount that the accelerator pedal is depressed (see, for example, JP-A-6-94151 and Japanese Patent No. 3070292). According to these devices, a motor driving current is supplied to three-phase stator coils wound on a stator core of a brushless DC motor in response to an accelerator position signal output from an accelerator position sensor that detects the amount that the accelerator pedal is depressed (accelerator position) to drive the brushless DC motor, whereby the position of the throttle valve is controlled, and the air is taken in by an amount that is controlled to be an optimum amount by the combustion chambers in the cylinders of the engine. The throttle position controller includes, as shown in
A valve position controller 105 controls the position of the throttle valve so that there is no deviation in position between the throttle position signal output from the throttle position sensor 101 and the accelerator position signal output from the accelerator position sensor 102. The rotor position detector 104 further transmits the data to a motor driver 107 through a rotor position detector 106 so as to vary the amount of motor driving current to the three-phase stator coils 103 and to vary the direction of the current. The rotor position detector 106 detects the position of the magnet rotor relative to the three-phase stator coils 103, so determines the motor driving current selectively fed to the two phases of the three-phase stator coils 103 that the magnet rotor produces a maximum output torque depending upon the detected result and, further, determines the direction of the motor driving current fed to the three-phase stator coils 103.
However, the above throttle position controllers include the throttle position sensor 101 for controlling the position of the throttle valve in addition to including the rotor position detector 104 for controlling the position of the magnet rotor relative to the stator coils 103 and the rotor position detector 106, posing a problem of an increased number of parts and boosting up the cost.
It is an object of the present invention to provide a valve position controller which is capable of decreasing the number of parts and the cost by using the signals output from the rotor position detector for calculating both the valve position control quantity and the motor current control quantity, omitting the throttle position (valve position) sensor.
According to the present invention, the present position of the valve is calculated (estimated) based on the signals corresponding to the rotational position of the magnet rotor relative to the stator coil of the three-phase brushless motor, that are output from the rotor position detector. A valve position control quantity is calculated so as to eliminate the difference between the present valve position that is calculated and a control target value, and a motor current control quantity is calculated based on the valve position control quantity that is calculated. Among the stator coils of the three phases, the stator coils of two phases are selectively driven based on the signals corresponding to the rotational position of the magnet rotor relative to the three-phase stator coils of the brushless motor output from the rotor position detector and on the motor current control quantity that is calculated. Namely, the magnet rotor of the brushless motor rotates and the present position of the valve is brought close to the target control value. Though the throttle position (valve position) sensor is omitted, the signals output from the rotor position detector are used for calculating both the valve position control quantity and the motor current control quantity making it possible to decrease the number of parts and the cost.
First Embodiment
The valve position controller for an internal combustion engine according to this embodiment is a throttle position controller for the internal combustion engine, which is provided in the intake system of the internal combustion engine such as a multi-cylinder (four cylinder, in this embodiment) gasoline engine (hereinafter referred to as the engine) mounted on a vehicle such as an automobile, and works to vary the throttle position corresponding to the rotational angle of the throttle valve 2 by driving a brushless DC motor 1 in response to the amount that the accelerator pedal is depressed by an operator (a driver) in order to control the engine rotational speed or the engine torque.
The valve position controller for the internal combustion engine includes double-throw throttle valves 2 for adjusting the amount of the air taken in by the combustion chambers of the cylinders of the engine, a valve shaft 3 that turns together with the throttle valves 2, a throttle body 4 for rotatably supporting the valve shaft 3, a power unit for driving the double-throw throttle valves 2 in a direction of opening the valves or in a direction of closing the valves, a return spring 5 for urging the double-throw throttle valves 2 in a direction of closing the valves (or in a direction of opening the valves), and an engine control unit (hereinafter referred to as ECU) 9 for electronically controlling a drive unit (specifically, a brushless DC motor 1) based on sensor signals from various sensors.
The power unit of this embodiment includes a brushless DC motor 1 which is a drive source, and a reduction gear mechanism which reduces the rotational speed of a motor shaft (output shaft) 11 of the brushless DC motor 1 at a predetermined reduction ratio, which are contained in an actuator casing 6 integrally assembled on an outer wall portion of the throttle body 4. The brushless DC motor 1 is an electric actuator which, when energized, causes the motor shaft 11 to rotate in a forward direction or in a reverse direction. A front end frame 12 is fastened and fixed to the surrounding of a motor insertion port 13 of the actuator casing 6 by using fastening fittings (not shown) such as fastening screws. The actuator casing 6 includes a motor housing portion 15 forming a motor-containing hole 14 where the brushless DC motor 1 is contained and held, and a gear housing portion 17 forming a gear chamber 16 where gears are rotatably held to constitute the reduction gear mechanism. The actuator casing 6 is integrally assembled at an end of a cylindrical wall portion 19 of the throttle body 4 on the opening side.
The reduction gear mechanism is constituted by a pinion gear 21 fixed to the outer periphery of the motor shaft 11 of the brushless DC motor 1, an intermediate reduction gear 22 that turns in mesh with the pinion gear 21, and a valve gear 23 that turns in mesh with the intermediate reduction gear 22. The reduction gear mechanism is used as a power transmission mechanism (torque transmission part) for transmitting the rotational power of the brushless DC motor 1 (motor output shaft torque) to the double-throw throttle valves 2 via the valve shaft 3. The pinion gear 21 is a motor gear that rotates integrally with the motor shaft 11 of the brushless DC motor 1. The intermediate reduction gear 22 is rotatably fitted to the outer periphery of a support shaft 24 which is a center of rotation. The intermediate reduction gear 22 has a large gear 25 that is brought in mesh with the pinion gear 21, and a small gear 26 that is brought in mesh with the valve gear 23. The valve gear 23 is fixed to the outer periphery of the valve shaft 3 at one end thereof in the axial direction.
Referring, here, to
The inner stator 7 is constituted by a stator core (armature core) 31 which is a laminated core obtained by laminating a number of soft magnetic materials (e.g., steel plates or silicon steel plates), and the three-phase coils (armature windings) 32 wound on the stator core 31. A plurality of teeth are formed maintaining an equal pitch in the outer peripheral portion of the stator core 31. On each tooth, there are wound the stator coils 32 of each of the U-phase, V-phase and W-phase in a concentrated manner. The stator coils 32 of the three phases are Y-connected. The stator coils 32 of the three phases, however, may be delta-connected.
The magnet rotor 8 is constituted by a rotor core 33 that fits to the outer periphery of the motor shaft 11, and twelve permanent magnets 34 fixed to the inner periphery of the rotor core 33 by using an adhesive. One end (lower end in the drawing) of the motor shaft 11 integral with the magnet rotor 8 is rotatably supported by a bearing holder 29 through a bearing 35, and the other end (upper end in the drawing) of the motor shaft 11 is rotatably supported by a cylindrical housing (motor housing) 37 via a bearing 36.
Here, referring to
The double-throw throttle valves 2 comprise circular disks fixed to the outer periphery of the valve shaft 3 or integrally formed together therewith having centers at points where the center axes of the throttle bores (intake passages) 40 of a circular shape in cross section intersect the center axis of rotation of the valve shaft 3. These throttle valves 2 are rotary valves having center axes of rotation in a direction nearly at right angles with the axial direction of an average flow of the intake air flowing through the throttle bores 40 in the throttle body 4. The throttle valves 2 change their rotational angle (valve position) over a rotational angular range of from the fully closed position where the amount of the intake air is a minimum through up to a fully opened position where the amount of the intake air is a maximum, to control the amount of the air taken into the combustion chambers of the cylinders of the engine. The double-throw throttle valves 2 are urged by the return spring 5 in a direction in which they are brought to the fully closed position (or in a direction in which they are brought to the fully opened position).
The valve shaft 3 constitutes the rotary axis of the double-throw throttle valves 2 and is defining the direction of the center of rotation (axial direction) which is nearly at right angles with the axial direction of the average flow of the intake air flowing through the throttle bores 40 in the throttle body 4, but is in parallel with the direction of center of the motor housing portion 15 in which the brushless DC motor 1 is fixed. One end of the valve shaft 3 in the axial direction works as a first bearing slide portion which rotatably slides in a first slide hole of a first bearing 42 held and fixed to a first bearing boss portion 41 of the throttle body 4. The other end of the valve shaft 3 in the axial direction works as a second bearing slide portion which rotatably slides in a second slide hole of a second bearing 44 held and fixed to a second bearing boss portion 43 of the throttle body 4.
A cylindrical joint portion (torque transmission part) 45 is integrally formed at one end of the valve shaft 3 in the axial direction thereof. A valve-side spring hook (first engaging portion) 46 is integrally attached to the other end of the valve shaft 3 in the axial direction to anchor one end of the return spring 5. A rotational angle limiting member 47 is integrally provided on the outer peripheral portion of the joint portion 45. On the outer peripheral portion of the rotational angle limiting member 47, there are integrally formed a full close stopper portion (not shown) which is a to-be-engaged portion that comes into direct or indirect contact with a full close-side mechanical stopper (full close stopper, see
At one end of the joint portion 45 in the axial direction, there is provided a protruded fitting portion that fits (loose fits) to a recessed fitting groove of the rotary shaft 27 of the valve gear 23 which is one of the constituent elements of the reduction gear mechanism. In this embodiment, a straight protruded portion is formed on the fitting portion of the joint portion 45 and a straight recessed portion is formed in the fitting groove of the rotary shaft 27 of the valve gear 23 in order to maintain a predetermined relative angle among the double-throw throttle valves 2, the valve shaft 3 and the valve gear 23, and to prevent a relative rotation between the valve shaft 3 and the valve gear 23.
The throttle body 4 is a throttle housing (valve housing) having two throttle bore walls 51 holding, therein, the double-throw throttle valves 2 so as to be opened and closed and permitting the air to flow in the center axial direction as it is taken in by the combustion chambers of the cylinders of the engine. The throttle body 4 is forming throttle bores 40 of a circular shape in cross section in the throttle bore walls 51 thereof permitting the intake air to flow into the combustion chambers in the cylinders of the engine. Namely, the throttle body 4 is a device which holds the double-throw throttle valves 2 so as to rotate over a range of from the fully closed position where the amount of the intake air is a minimum through up to the fully opened position where the amount of the intake air is a maximum. The throttle body 4 is fastened and fixed to the intake manifold of the engine or to the surge tank by using fastening fittings (not shown) such as fixing bolts or fastening screws.
The throttle bores 40 are provided with an air inlet portion for taking in the air from an air cleaner through the engine intake pipe and an air outlet portion for flowing the intake air into the intake manifold of the engine or into the surge tank.
The return spring 5 is contained in a spring housing portion 52 integrally attached to the outer wall of the throttle bore wall 51 of the throttle body 4, and is wound on the outer periphery at the other end of the valve shaft 3 in the axial direction. One end of the return spring 5 is held (or anchored) by the valve-side spring hook 46 of the valve shaft 3, and the other end of the return spring 5 is held (or anchored) by a housing-side spring hook (second engaging portion) 53 provided on the inner wall surface of the spring housing portion 52.
Referring to
The microcomputer is so constituted that the sensor signals from various sensors such as an accelerator position sensor 61 for detecting the amount the accelerator pedal is depressed by the driver (amount the accelerator pedal is operated), an air flow meter (intake air amount sensor) 62 for detecting the amount of the air taken in by the engine, and a crank angle sensor 63 for detecting the rotational angle of the crankshaft of the engine, are put to the A/D conversion through an A/D converter, and are input to the microcomputer. Here, the microcomputer works as means for detecting the rotational speed of the engine by measuring the time interval of NE pulse signals output from the crank angle sensor 63.
The motor current control circuit 10 is mounted on a circuit board 64 incorporated in the cylindrical housing 37 of the brushless DC motor 1. The motor current control circuit 10 is so constituted as to receive electric signals output from a rotor position detector 65 that detects the rotational position (rotor position) of the magnet rotor 8 of the brushless DC motor 1. Further, the motor current control circuit 10 is a drive IC integrating, on a one-chip microcomputer, the functions of a valve position calculator (valve position calculation means) 71, a motor angle controller (control quantity calculation means) 72 and a motor driver (motor driver circuit) 73, and is integrally mounted on the circuit board 64 on the side opposite to the side of the magnet rotor 8.
Here, the rotor position detector 65 is a rotor rotational position sensor that produces electric signals corresponding to the rotational position of the magnet rotor 8 relative to the three-phase stator coils 32 of the brushless DC motor 1 (rotational position of the magnet rotor 8, rotational angle of the motor) and to the rotational direction of the magnet rotor 8. As shown in
The three Hall ICs 65u, 65v and 65w are the ICs (integrated circuits comprising amplifier circuits and Hall elements (noncontact type magnetic detector elements) that detect the rotational position of the magnet rotor 8 of the brushless DC motor 1 (motor angle) and the direction in which the magnet rotor 8 rotates. The Hall ICs 65u, 65v and 65w generate electromotive forces upon sensing the magnetic field generated by the twelve permanent magnets 34, and produce voltage signals corresponding to the density of magnetic flux intersecting the Hall ICs 65u, 65v and 65w. The three Hall ICs 65u, 65v and 65w may have a function for electrically trimming, from an external unit, programs for adjusting the output gains for the magnetic flux density, for adjusting the offset and for correcting the temperature characteristics and may, further, have a function for self-diagnosing the breakage of the wires and the short-circuit.
The valve position calculator 71 works as valve position calculation means for calculating the throttle position (valve position) corresponding to the rotational angle of the double-throw throttle valves 2 based on the electric signals output from the rotor position detector 65. Concretely, as shown in
Valve position=counted number (times)×(360 [deg]/number of magnetic poles P/gear ratio N)
Valve position resolution=360[deg]/number of magnetic poles P/gear ratio N
In this embodiment, a relationship P/N>360/5=72 is maintained so that the resolution is not larger than 5 degrees.
The motor angle controller 72 has a function for calculating a valve position control quantity based upon a deviation in position between a target control value (target throttle position, target valve position, control instruction value) set depending upon the engine operating conditions and a real throttle position (valve position that is calculated) so as to eliminate the deviation in position. The motor angle controller 72, further has a function for calculating the motor current control quantity based on the valve position control quantity that is calculated.
Here, the valve position control quantity is calculated based on a target throttle position (target valve position) or a target valve position thereof calculated by the ECU 9 relying on the real throttle position (calculated valve position), engine rotational speed and accelerator position signal (by taking the deflection of the torque transmission part into consideration) in accordance with a proportional integration/differentiation control (PID control) so as to eliminate the difference from the target valve position corrected by the motor angle controller 72. The motor current control quantity includes an output duty (amount of current) calculated as a duty ratio signal that is PWM-converted (pulse-modulated) so as to eliminate the deviation between the target valve position and the real throttle position (calculated valve position), and the direction of motor drive current flowing into the stator coils 32 of two phases among the stator coils 32 of the three phases.
The motor driver 73 has a function of forming an output current duty (motor drive current) from the output duty (amount of current) set by the electric signals from the rotor position detector 65, i.e., from the three Hall ICs 65u, 65v and 65w and by the motor angle controller 72, and selectively drives the stator coils 32 of two phases among the stator coils 32 of the three phases. The motor driver 73 has semiconductor switching elements for selectively changing over the direction of feeding the motor drive currents to the stator coils 32 of two phases among the stator coils 32 of the three phases.
Control Method of the First Embodiment
Next, a method of controlling the valve position controller for an internal combustion engine according to the embodiment will be briefly described with reference to
First, at the time of the fully closed learn control (fully closed=0°), the PWM-converted (pulse-modulated) duty ratio is set to be the current duty ratio (e.g., −70%) at the time of the fully closed learn control to maintain the double-throw throttle valves 2 at the fully closed position at step S11 in
When the determined result is YES at step S12, the learning time counter (T1) is counted up by a sampling time (Tc) at step S14. Next, it is determined if the learning time counter (T1) is greater than the learning end time (e.g., 100 msec) at step S15. When the determined result is NO, the routine returns back to the judging processing of step S12. When the determined result at step S15 is YES, the valve position counter (Cv) is set to the throttle position=valve position 0 that corresponds to the fully closed position of the double-throw throttle valves 2, and the learn end flag (X1f) is set to 1 at step S16. Thereafter, the reference position learn control routine of
At the time of the fully opened learn control (fully opened=90°), the PWM-converted (pulse-modulated) duty ratio is set to be the current duty ratio (e.g., 70%) at the time of the fully opened learn control to maintain the double-throw throttle valve 2 at the fully opened position at step S21 in
When the determined result is YES at step S22, the learning time counter (T1) is counted up by a sampling time (Tc) at step S24. Next, it is determined if the learning time counter (T1) is greater than the learning end time (e.g., 100 msec) at step S25. When the determined result is NO, the routine returns back to the judging processing of step S22. When the determined result at step S25 is YES, the valve position counter (Cv) is set to the throttle position=valve position 90/(360/gear ratio N/number of magnetic poles P) that corresponds to the fully opened position of the double-throw throttle valves 2, and the learn end flag (X1f) is set to 1 at step S26. Thereafter, the reference position learn control routine of
A procedure for processing the valve position calculation executed by the valve position calculator (valve position calculation means) 71 will be described by using a flowchart of
First, it is determined if the count-up condition is holding at step S31. The count-up condition holds when the signal conditions (ssta) output from the rotor position detector 65 vary as described below, i.e., when the electric signals output from the three Hall ICs 65u, 65v and 65w vary as described below. The count-up condition does not hold in other cases. Namely, the count-up condition holds when the signals vary in a manner of 1→2, 2→3, 3→4, 4→5, 5→6 or 6→1.
When the determined result at step S31 is YES, the valve position counter (Cv) is counted up at step S32. The procedure, thereafter, goes out of the valve position calculation routine of
When the determined result at step S33 is YES, the valve position counter (Cv) is counted down at step S34. The procedure, thereafter, goes out of the valve position calculation routine of
Operation of the First Embodiment
The operation of the valve position controller for an internal combustion engine according to the embodiment will now be briefly described with reference to
When the driver depresses the accelerator pedal, an accelerator position signal is input to the ECU 9 from the accelerator position sensor 61. The ECU 9 sends a target control value (target throttle position) to the motor current control circuit 10. On the other hand, the valve position calculator 71 counts the number of shifts of the conditions of the electric signals corresponding to the rotational position of the magnet rotor 8 relative to the three-phase stator coils 32 of the brushless DC motor 1 output from the rotor position detector 65, i.e., counts the number of shifts of the conditions of the electric signals output from the three Hall ICs 65u, 65v and 65w, and calculates the total rotational angle of the magnet rotor 8 of the brushless DC motor 1, i.e., calculates the throttle position corresponding to the rotational angle of the double-throw throttle valves 2.
Next, the motor angle controller 72 calculates the valve position control quantity based on a target throttle position (target valve position) or a target valve position thereof calculated by the ECU 9 relying on the real throttle position (calculated valve position), engine rotational speed and accelerator position signal (by taking the deflection of the torque transmission part into consideration) in accordance with a proportional integration/differentiation control (PID control) so as to eliminate the difference from the target valve position corrected by the motor angle controller 72. Further, the motor angle controller 72 determines an output duty (amount of current) calculated as a duty ratio signal that is PWM-converted (pulse-modulated) so as to eliminate the deviation between the target control value (target throttle position) and the real throttle position (calculated valve position), and the direction of motor driving current flowing into the stator coils 32 of two phases among the stator coils 32 of the three phases.
Next, the motor driver 73 forms an output current duty (motor driving current) from the output duty (amount of current) set by the electric signals output from the rotor position detector 65, i.e., from the three Hall ICs 65u, 65v and 65w and by the motor angle controller 72, and selectively drives the stator coils 32 of two phases among the stator coils 32 of the three phases. Here, the motor driver 73 selectively changes over the direction of feeding the motor driving currents to the stator coils 32 of two phases among the stator coils 32 of the three phases.
Thus, the motor driving current flows to the stator coils 32 of two phases among the stator coils 32 of the three phases of the brushless DC motor 1, and the motor shaft 11 of the brushless DC motor 1 turns so that the double-throw throttle valves 2 are turned by a predetermined angle. The torque of the brushless DC motor 1 is transmitted to the pinion gear 21, intermediate reduction gear 22 and valve gear 23. Therefore, the valve gear 23 and the valve shaft 3 coupled to the rotary shaft 27 of the valve gear 23 through the joint portion 45, are turned by a rotational angle corresponding to the amount the accelerator pedal is depressed against the urging force of the return spring 5 (e.g., against the urging force in the direction of fully closing the valves). Therefore the double-throw throttle valves 2 are turned in a direction in which they are opened (fully opening direction) toward the fully opened position from the fully closed position, and the throttle bores 40 of the throttle body 4 are opened by a predetermined valve position, causing the engine rotational speed to change into a speed corresponding to the amount the accelerator pedal is depressed.
Effect of the First Embodiment
In the valve position controller for the internal combustion engine according to this embodiment as described above, the throttle position corresponding to the rotational angle of the double-throw throttle valves 2 is calculated based on the signal conditions (ssta) from the rotor position detector 65 that detects the rotational position (motor angle) of the magnet rotor 8 of the brushless DC motor 1 and the rotational direction of the magnet rotor 8, i.e., based on the electric signals output from the three Hall ICs 65u, 65v and 65w. The valve position control quantity for the double-throw throttle valves 2 is so calculated as to eliminate the difference between the real throttle position that is calculated (valve position found by calculation) and the target control value (target valve position, instructed position).
Further, the motor current control quantity for the brushless DC motor 1 is so calculated as to eliminate the difference between the target control value (target throttle position) and the real throttle position (valve position that is calculated). Concretely, there are determined an output duty (amount of current) calculated as a duty ratio signal that is PWM-converted (pulse-modulated) so as to eliminate the deviation between the target control value (target throttle position) and the real throttle position (calculated valve position), and the direction of motor driving current flowing into the stator coils 32 of two phases among the stator coils 32 of the three phases. Despite of omitting the throttle position (valve position) sensor, therefore, the signal conditions (ssta) from the rotor position detector 65 are used, i.e., the electric signals output from the three Hall ICs 65u, 65v and 65w are used for calculating both the valve position control quantity and the motor current control quantity making it possible to decrease the number of parts and the cost.
Here, means for indirectly detecting the valve position of the throttle position controller shown in JP-A-6-94151 and in Japanese Patent No. 3070292, do not directly detect the valve position from the electric signals (sensor outputs) output from a rotor position detector means 104, but indirectly detect the valve position by counting the signals for changing the current control transistor over to the three-phase stator coils 103 determined by a motor current driver 107 based on the sensor output. According to the method of indirectly detecting the valve position, there remains a problem in that the rotation of the throttle valve cannot be detected in case the throttle valve has rotated due to the intake air that flows through the throttle bores (intake passages) of the throttle body when the current is interrupted from flowing into the three-phase stator coils 103 of the brushless DC motor. According to the above method of indirectly detecting the valve position, further, there remains another problem in that the absolute valve position of the throttle valve (relative position from the reference position) cannot be detected.
In the valve position controller for the internal combustion engine according to this embodiment, therefore, the valve position calculator 71 in the motor current control circuit 10 incorporates a valve position counter (Cv) for counting the signal conditions (ssta) output from the rotor position detector 65, i.e., for counting the number of shifts of the conditions of the electric signals output from the three Hall ICs 65u, 65v and 65w. Based on the number counted by the valve position counter (Cv), the valve position calculator 71 calculates the throttle position (valve position) corresponding to the present position (rotational angle) of the double-throw throttle valves 2. This makes it possible to monitor (directly detect), at all times, the signal conditions (ssta) output from the rotor position detector 65, i.e., to monitor the number of shifts of the conditions of electric signals output from the three Hall ICs 65u, 65v and 65w, and to accurately calculate or estimate the throttle position (valve position) at all times. Upon executing the procedure for processing the reference position learn control for the magnet rotor 8 illustrated in the flowcharts of
Further, the three functions of the valve position calculator 71, motor angle controller 72 and motor driver 73 are integrated on a one-chip microcomputer, eliminating a wire harness for coupling the valve position calculator 71 to the motor angle controller 72, eliminating a wire harness for coupling the motor angle controller 72 to the motor driver 73, and eliminating the transmitter/receiver circuit and input/output circuit, contributing to decreasing the number of power source wires. It is, therefore, allowed to realize the motor current control circuit 10 in a compact size and, further, to decrease the number of parts and the cost.
Upon incorporating the three functions of the valve position calculator 71, motor angle controller 72 and motor driver 73 integrated on one-chip microcomputer and the function of the rotor position detector 65 in the cylindrical housing 37 of the brushless DC motor 1, further, it is allowed to eliminate the wire harness for coupling the rotor position detector 65, i.e., for coupling the three Hall ICs 65u, 65v and 65w to the valve position calculator 71 or to the motor driver 73, and to eliminate the transmitter/receiver circuit and the input/output circuit, making it possible to decrease the number of the power source lines. It is, therefore, made possible to further decrease the number of parts and the cost. Moreover, the rotor position detector 65, valve position calculator 71, motor angle controller 72 and motor driver 73 are integrated on a piece of circuit board 64 which is simply incorporated in the cylindrical housing 37 of the brushless DC motor 1 to finish the assembling of the sensors and the circuits facilitating the assembling.
Second Embodiment
Here, in the throttle position controller disclosed in JP-A-6-94151 and in Japanese Patent No. 3070292, in case the shift of the output condition of the rotor position detecting means 104 is skipped due to noise or the like, there may occur a large difference between the valve position that is recognized of the throttle valve and the real valve position of the throttle valve if there is provided no means for compensating the skipping and if the valve position of the throttle valve is calculated based on a signal output from the rotor position detection means 104. Depending upon the cases, further, the emission will be adversely affected.
Further, considered below is a case where the output conditions of the three Hall ICs 65u, 65v and 65w shift in order of 1→2→3 accompanying the change in the rotational angle of the magnet rotor 8 of the brushless DC motor 1 as shown in
Therefore, the valve position control device for the internal combustion engine of this embodiment is equipped with compensation means (flowchart of
When the result determined at step S33 is NO, it is determined if the condition skip-up direction condition is holding at step S35. When the determined result is YES, the valve position counter (Cv) is skipped up at step S36. Thereafter, the procedure goes out of the valve position calculation routine of
When the result determined at step S35 is NO, it is determined if the condition skip-down direction condition is holding at step S37. When the determined result is YES, the valve position counter (Cv) is skipped down at step S38. Thereafter, the procedure goes out of the valve position calculation routine of
When the result determined at step S37 is NO, the valve position counter (Cv) is not varied. Namely, the present valve position counter (Cv) is maintained at step S39. Thereafter, the procedure goes out of the valve position calculation routine of
In the valve position controller for the internal combustion engine of this embodiment as described above, the count number of the valve position counter (Cv) is increased or decreased by an amount that is skipped in case the shift of the condition of the electric signal (sensor output) from any one of the three Hall ICs 65u, 65v, 65w is skipped. By specifying the order of normal shifts of the condition, therefore, it is allowed to estimate the direction in which the magnet rotor 8 rotates and the amount of rotational angle (motor angle) even in case skip has occurred to a small degree improving the robustness against a large disturbance torque such as backfire and against the noise affecting the electric signal (sensor output) produced from any one of the three Hall ICs 65u, 65v and 65w. Therefore, it seldom happens to miss the counting of the number of shifts of the conditions of electric signals output from the three Hall ICs 65u, 65v and 65w, and it becomes little probable that a large difference occurs between the calculated valve position of the double-throw throttle valves 2 and the real valve position thereof preventing the emission from being adversely affected.
Third Embodiment
In the valve position controller for the internal combustion engine of this embodiment, the three normal Hall ICs 65u, 65v and 65w can assume only six output conditions (six patterns) shown in
Further, in case two or more conditions skip like 1→4 (conditions 2 and 3 or conditions 6 and 5 are skipped) as the shift of the signal conditions (ssta) output from the rotor position detector 65, i.e., as the shift of the conditions of the electric signals output from the three Hall IC's 65u, 65v and 65w, this condition is detected as a malfunctioning condition by the malfunctioning Hall IC detector 74, and a suitable processing is executed like leaning again the reference position learn control of the magnet rotor 8 shown in the flowcharts of
The throttle position controllers disclosed in JP-A-6-94151 and in Japanese Patent No. 3070292 are capable of detecting which one of the rotor position detector 104 or the motor driver 107 is defective relying upon abnormal order of changing over the current, but are not capable of isolating them, with which a suitable countermeasure cannot be taken on the engine side or on the vehicle side in a case a trouble is detected. When the supply of current to the three-phase stator coils 103 of the brushless DC motor is discontinued, further, it is not allowed to detect abnormal condition in the rotor position detector 104 or in the motor driver 107.
Therefore, the malfunctioning Hall IC detector 74 of this embodiment includes a first malfunction discrimination means for discriminating whether the signal conditions (ssta) output from the rotor position detector 65, i.e., whether the conditions of the electric signals (sensor outputs) output from the three Hall ICs 65u, 65v and 65w are abnormal or normal, and a second malfunction discrimination means for discriminating whether the order of shift of the signal conditions (ssta) output from the rotor position detector 65, i.e., whether the order of shift of the conditions of electric signals (sensor outputs) output from the three Hall ICs 65u, 65v and 65w is abnormal or normal. By monitoring the signal conditions (ssta) output from the rotor position detector 65, i.e., by monitoring the electric signals (sensor outputs) output from the three Hall ICs 65u, 65v and 65w, therefore, the malfunctioning condition can be detected in the three Hall ICs 65u, 65v and 65w independently from the malfunctioning motor driver 73, making it possible to precisely detect the malfunctioning condition in the three Hall ICs 65u, 65v and 65w. Even when the supply of current to the three-phase stator coils 32 of the brushless DC motor 1 is interrupted, the malfunctioning condition can be detected in the three Hall ICs 65u, 65v and 65w.
Therefore, a highly reliable system is realized by detecting the malfunctioning conditions (malfunctioning output conditions of the three Hall ICs 65u, 65v and 65w) in the electric signals (sensor outputs) output from the three Hall ICs 65u, 65v and 65w, and by detecting abnormal shift of the conditions of the electric signals (sensor outputs) output from the three Hall ICs 65u, 65v and 65w (abnormal shift of the output conditions of the three Hall ICs 65u, 65v and 65w). Here, when it is determined by the malfunctioning IC detector 74 that the order of shift of the conditions of the electric signals (sensor outputs) output from the three Hall ICs 65u, 65v and 65w is not normal, a suitable processing is executed such as learning again the reference position learn control of the magnet rotor 8 illustrated in the flowcharts of
Fourth Embodiment
In the valve position controller for the internal combustion engine of this embodiment, a large disturbance torque may generate in the engine intake pipe communicated with the intake ports of the engine and, particularly, in the throttle bores 40 of the throttle body 4 due to the backfire (a phenomenon in which the combustion of a mixture is not completed during the combustion stroke in the combustion chamber in each cylinder of the engine, but lasts until the intake valve, which is for opening and closing the intake port of the cylinder of the engine, is opened in the next intake stroke). Due to the large disturbance torque, in this case, the double-throw throttle valves 2 turn at a high speed, whereby the signal conditions (ssta) output from the rotor position detector 65, i.e., the rate of change of the conditions of electric signals (sensor outputs) output from the three Hall ICs 65u, 65v and 65w become greater than the sampling speed, and the number of shifts of the conditions of electric signals (sensor outputs) output from the three Hall ICs 65u, 65v and 65w may be erroneously counted by the valve position counter (Cv) of the valve position calculator 71. To cope with this, if it is attempted to increase the speed for sampling the electric signals (sensor outputs) output from the three Hall ICs 65u, 65v and 65w, then, the sampling of a very high speed must be executed, boosting up the cost.
According to this embodiment, therefore, the motor current control circuit 10 is provided with a current detector (malfunction detector) 75 for detecting malfunctioning input which is very larger than the expected load torque based on a counter-electromotive force produced by the motor driving current flowing from the motor driver 73 into the three-phase stator coils 32 of the brushless DC motor 1. The current detector 75 is compensation means for compensating the count miss caused by a large disturbance torque. A counter-electromotive force generates on the three-phase stator coils 32 of the brushless DC motor 1 when the double-throw throttle valves 2 turn at a high speed due to the large disturbance torque. As a result, there occurs a change in the motor driving current flowing into the three-phase stator coils 32 of the brushless DC motor 1.
When the malfunctioning input which is very greater than the estimated load torque is detected in detecting the amount of change in the motor driving current by the current detector 75, i.e., when the amount of change in the motor driving current flowing into the three-phase stator coils 32 of the brushless DC motor 1 has exceeded a predetermined value, the reference position learn control for the magnet rotor 8 illustrated in the flowcharts of
Even though the speed is not increased for sampling the electric signals (sensor outputs) output from the three Hall ICs 65u, 65v and 65w, the count miss for the number of shifts of the conditions of electric signals (sensor outputs) output from the three Hall ICs 65u, 65v and 65w can be eliminated without boosting up the cost. Further, by shortening the period (for receiving signals from the rotor position detector 65) for sampling the electric signals (sensor outputs) output from the three Hall ICs 65u, 65v and 65w to be very shorter than a minimum period for shifting the conditions of electric signals output from the three Hall ICs 65u, 65v and 65w, it is made possible to prevent the count miss of the number of shifts of the conditions of electric signals output from the three Hall ICs 65u, 65v and 65w, making it possible to detect the present position (valve position) of the double-throw throttle valves 2 maintaining high reliability.
Fifth Embodiment
The rotor position detector (rotor position detection means) 65 of this embodiment comprises three Hall ICs 65u, 65v and 65w that are disposed maintaining a distance of, for example, 40 degrees in a direction in which the magnet rotor 8 rotates to generate an electromotive force upon sensing the magnetic field generated by permanent magnets 34 that are arranged in a number of twelve, and to produce output signals in response to the density of the magnetic flux that intersects them. Here, if one Hall IC 65w is malfunctioning being fixed to be high (high level) among the three Hall ICs 65u, 65v and 65w, the output that should be (110) in the condition 3 becomes (111).
As shown in the control logic of
After the malfunctioning Hall IC is specified, the number of shifts of the conditions of electric signals output from the remaining two Hall ICs is counted disregarding the electric signals output from the malfunctioning Hall IC, and a throttle position (valve position) corresponding to the present position (rotational angle) of the double-throw throttle valves 2 is calculated (detected) based on the counted number. Concretely, at the time of the condition 6, the output conditions of the two Hall ICs 65u and 65v become {uv}={00} establishing the condition D of when the Hall IC 65w is malfunctioning. At the time of the condition 1 where the magnet rotor 8 of the brushless DC motor 1 has turned in the fully opening direction, the output conditions of the two Hall ICs 65u and 65v become {uv}={10} establishing the condition A of when the Hall IC 65w is malfunctioning. Even at the time of the condition 2 where the magnet rotor 8 of the brushless DC motor 1 has turned in the fully opening direction, the output conditions of the two Hall ICs 65u and 65v become {uv}={10} maintaining the condition A of when the Hall IC 65w is malfunctioning.
Further, at the time of the condition 3 where the magnet rotor 8 of the brushless DC motor 1 has turned in the fully opening direction, the output conditions of the two Hall ICs 65u and 65v become {uv}={11} establishing the condition B of when the Hall IC 65w is malfunctioning. Moreover, at the time of the condition 4 where the magnet rotor 8 of the brushless DC motor 1 has turned in the fully opening direction, the output conditions of the two Hall ICs 65u and 65v become {uv}={01} establishing the condition C of when the Hall IC 65w is malfunctioning. At the time of the condition 5 where the magnet rotor 8 of the brushless DC motor 1 has turned in the fully opening direction, too, the output conditions of the two Hall ICs 65u and 65v become {uv}={01} maintaining the condition C of when the Hall IC 65w is malfunctioning. Further, at the time of the condition 6 where the magnet rotor 8 of the brushless DC motor 1 has turned in the fully opening direction, the output conditions of the two Hall ICs 65u and 65v become {uv}={00} establishing the condition D of when the Hall IC 65w is malfunctioning.
As described above, while the magnet rotor 8 of the brushless DC motor 1 is turning in the fully opening direction, the valve position calculator 71 increases the valve position counter (Cv) by two (skips up 2) when the condition in the next turn has shifted like condition A→condition B or condition C→condition D. Further, the valve position counter (Cv) is increased by one (counted up by 1) when the condition has shifted in the next turn like condition B→condition C or condition D→condition A. Further, while the magnet rotor 8 of the brushless DC motor 1 is turning in the fully closing direction, the valve position calculator 71 decreases the valve position counter (Cv) by two (skips down 2) when the condition in the next turn has shifted like condition C→condition B or condition A→condition D. Further, the valve position counter (Cv) is decreased by one (counted down by 1) when the condition has shifted in the next turn like condition B→condition A or condition D→condition C.
When one Hall IC 65w among the three Hall ICs 65u, 65v and 65w is malfunctioning being fixed to the low (low level), the output condition that should be (001) under the condition 6 becomes (000). Therefore, when one Hall IC 65w is malfunctioning being fixed to the low (low level), too, the malfunctioning Hall IC can be specified like when one Hall IC 65w is malfunctioning being fixed to the high (high level). After the malfunctioning Hall IC is specified, the number of shifts of the conditions of electric signals output from the remaining two Hall ICs is counted disregarding the electric signals output from the malfunctioning Hall IC in the same manner as described above, and a throttle position (valve position) corresponding to the present position (rotational angle) of the double-throw throttle valves 2 is calculated (detected) based on the counted number.
In the valve position controller for the internal combustion engine according to this embodiment as described above, when any one of the three Hall ICs 65u, 65v and 65w is detected to be malfunctioning, the number of shifts of the conditions of electric signals output from the remaining two Hall ICs is counted to calculate the throttle position (valve position) that corresponds to the present position (rotational angle) of the double-throw throttle valves 2 avoiding such a situation that the present position (valve position) of the double-throw throttle valves 2 is lost simply because any one of the three Hall ICs 65u, 65v and 65w is malfunctioning. Even under the above situation, therefore, the valve position calculator 71 executes a suitable processing (counting the valve position counter (Cv)) based on the malfunctioning sensor data.
Sixth Embodime
In the valve position controller for the internal combustion engine of this embodiment, a deviation may occur between the calculated valve position and the real valve position from the rotational position (rotational angle) of the magnet rotor 8 of the brushless DC motor 1 due to a gap (backlash) between the teeth surfaces of when the pinion gear is in mesh with a large gear 25 of the intermediate reduction gear 22, which are constituent elements of the reduction gear mechanism, due to a gap (backlash) between the teeth surfaces of when the small gear 26 of the intermediate reduction gear 22 is in mesh with the valve gear 23, i.e., due to the magnitude of play (backlash) of the reduction gears in the direction of rotation, due to the play of the coupling portion (valve shaft coupling portion) between the rotary shaft 27 of the valve gear 23 and the joint portion 45 of the valve shaft 3, and due to the play of the coupling portion (motor output shaft-coupling portion) between the motor shaft 11 of the brushless DC motor 1 and the pinion gear 21. Namely, a deviation may occur between the real valve position and the calculated value (calculated valve position) of the throttle position (valve position) corresponding to the present position (rotational angle) of the double-throw throttle valves 2 based on the number of shifts of the conditions of signals output from the three Hall ICs 65u, 65v and 65w.
Therefore, the valve position controller for the internal combustion engine of this embodiment is provided with a return spring 5 for urging the double-throw throttle valves 2 in a direction in which they are fully opened to bring the reduction gears into engagement with the motor output shaft-coupling portion at all times in one direction of the backlash and of the play. Namely, the reference position learn control is executed to learn the reference position of the magnet rotor 8 of the brushless DC motor 1 in a state where the double-throw throttle valves 2 are positioned at the valve position (idling position) at where they are abut to the mechanical stopper (full close stopper) 91 of the fully closed side that is against the urging force of the return spring 5. This makes it possible to eliminate the mismatching between the calculated valve position and the real valve position from the rotational position (rotational angle) of the magnet rotor 8 of the brushless DC motor 1 caused by the backlash among the reduction gears, play at the valve shaft-coupling portion and play at the motor output shaft-coupling portion. It is also allowable to provide the return spring 5 that urges the double-throw throttle valves 2 in the direction in which they are fully closed to bring the reduction gears into engagement with the motor output shaft-coupling portion at all times in one direction of the backlash and of the play, and execute the reference position learn control for learning the reference position of the magnet rotor 8 of the brushless DC motor 1 in a state where the double-throw throttle valves 2 are positioned at a valve position (idling position) where they are abut to the mechanical stopper (full open stopper) 92 of the fully opened side that is against the urging force of the return spring 5.
Seventh Embodiment
If there occurs a breakage (e.g., breakage of gear, abnormally increased backlash) in one or more of the reduction gears among the pinion gear 21, intermediate reduction gear 22 and valve gear 23 which are the elements constituting the reduction gear mechanism, in the coupling portion (valve shaft-coupling portion) between the rotary shaft 27 of the valve gear 23 and the joint portion 45 of the valve shaft 3, or in the coupling portion (motor output shaft-coupling portion) between the motor shaft 11 of the brushless DC motor 1 and the pinion gear 21 in the valve position controller for the internal combustion engine of this embodiment, mismatching occurs between the calculated valve position and the real valve position from the rotational position (rotational angle) of the magnet rotor 8 of the brushless DC motor 1. If the mismatching is left to stand, the emission may be adversely affected.
In this embodiment, therefore, the motor current control circuit 10 is provided with means 76 for detecting the malfunction of the power transmission mechanism to detect abnormal condition in the reduction gears, in the valve shaft-coupling portion and in the motor output shaft-coupling portion in case the counted number of the valve position counter (Cv) of the valve position calculator 71 deviates from a predetermined range (range in which the valve position can be counted), or in case the signal conditions (ssta) from the rotor position detector 65 are continuously shifting, i.e., in case the conditions of electric signals (sensor outputs) output from the three Hall ICs 65u, 65v and 65w are shifting for longer than a predetermined period of time (e.g., 200 msec) during the reference position learn control for learning the reference position of the magnet rotor 8 of the brushless DC motor 1.
Therefore, the malfunctioning condition is detected if a breakage (e.g., breakage of gear, abnormally increased backlash) occurs in the reduction gears, in the valve shaft-coupling portion or in the motor output shaft-coupling portion, and if mismatching occurs between the calculated valve position and the real valve position from the rotational position (rotational angle) of the magnet rotor 8 of the brushless DC motor 1. When the malfunction in the power transmission mechanism is detected from the rotational position (rotational angle) of the magnet rotor 8 of the brushless DC motor 1 that is lying outside the range, acoustic indication means such as buzzer or voice means is actuated or visual indication means such as an indicator lamp or character data is actuated promoting the driver to have the power transmission mechanism repaired or renewed, so that the mismatching between the calculated valve position and the real valve position from the rotational position (rotational angle) of the magnetic rotor 8 of the brushless DC motor 1 will not be left to stand and that the emission will not be adversely affected. Further, in case the malfunction in the power transmission mechanism is detected from the rotational position (rotational angle) of the magnet rotor 8 of the brushless DC motor 1 that is lying outside the range, a suitable procedure may be executed such as learning again the reference position learn control of the magnet rotor 8 illustrated in the flowcharts of
Eighth Embodiment
The valve position controller for the internal combustion engine of this embodiment includes a brushless DC motor 1 which is a drive source, a throttle valve 2 for adjusting the amount of the air taken into the combustion chambers of the cylinders of the engine, a valve shaft 3 that turns integrally with the throttle valve 2, a throttle body 4 for rotatably supporting the valve shaft 3, a return spring 5 for urging the throttle valve 2 in a direction in which it closes (or in a direction in which it opens), an ECU 9 for controlling the motor driving current fed to the three-phase stator coils 32 of the brushless DC motor 1 based on at least a throttle position signal from the accelerator position sensor 61, and a motor current control circuit 10 (a driving IC integrating three functions of the valve position calculator 71, motor angle controller 72 and motor driver 73 on the one-chip microcomputer). The throttle valve 2 may be in the form of a multi-throw throttle valves having not less than three valves.
Modified Embodiments
In this embodiment, the valve position controller of the invention is applied to the valve position controller for the internal combustion engine which controls the throttle position (valve position) corresponding to the rotational angle of the throttle valve 2 used in the throttle controller for the internal combustion engine by driving the brushless DC motor 1 depending upon the amount the accelerator pedal is depressed by the driver. However, the valve position controller of the invention may also be applied to the valve position controller for the internal combustion engine that controls the valve position of the multi-throw variable intake valves used for the variable intake system of the internal combustion engine. The variable intake valves are the air control valves for the internal combustion engine which varies the length or the sectional area of the intake passage of the intake manifold depending upon the rotational speed of the engine. The variable intake system for the internal combustion engine is a device for increasing the engine output shaft torque (engine torque) irrespective of the rotational speed of the engine by changing over the intake passage by using the valve bodies of the variable intake valves so as to lengthen the intake passage of the intake manifold when the engine is running in the low- to medium-speed regions, and by changing over the intake passage by using the valve bodies of the variable intake valves so as to shorten the length of the intake passage of the intake manifold when the engine is running in the high-speed region.
Further, the valve of the invention may be applied to the intake control valve which controls the amount of the air taken into the combustion chambers of the engine, to the exhaust control valve which controls the amount of the gas exhausted from the combustion chambers of the engine, to the idling speed control valve which controls the amount of the intake air by-passing the throttle valve, and to the exhaust gas recirculation control valve (EGR control valve) which controls the amount of the exhaust gas partly recirculated from the engine exhaust gas into the intake passage. The valve of the invention may be further applied to the intake air flow control valve such as a swirl control valve or a so-called swirl stream control valve that causes the intake air to produce a swirling stream in the transverse direction as it flows into the combustion chamber of the cylinder of the engine from the intake port of the engine. The valve of the invention may further be applied to the intake air stream control valve such as a tumble control valve or a so-called tumble stream control valve which causes the intake air to produce a swirling stream in the longitudinal direction as it flows into the combustion chamber of the cylinder of the engine from the intake port of the engine. In addition to the rotary valves such as the butterfly valves that are described above, the valve of the invention may further be applied to the poppet valves, shutter valves and door valves which are supported at the one side thereof only.
The above embodiments have dealt with the cases of using the three Hall ICs 65u, 65v and 65w integrating the Hall elements (noncontact-type magnetic detector elements) with the amplifier circuits, as noncontact-type magnetic detector elements (rotational angle sensors). As the noncontact-type magnetic detector elements (rotational angle sensors), however, there may be further used Hall elements alone or the reluctance elements. The noncontact-type magnetic detector elements (rotational angle sensors) may be arranged in a magnetic gap formed between a pair of magnetic members (yokes) that are magnetized by the permanent magnets. The noncontact-type magnetic detector elements may be provided in any number which is not smaller than 2 to detect the rotational position (motor rotational angle) and the rotational direction of the magnet rotor 8 of the brushless DC motor 1. Further, the brushless motor may be the one of the outer stator type (inner rotor type). Instead of the brushless DC (direct current) motor 1, further, there may be used a brushless AC (alternating current) motor 1 or an AC (alternating current) motor such as a three-phase induction motor.
Number | Date | Country | Kind |
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2004-212218 | Jul 2004 | JP | national |
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Number | Date | Country |
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H06-94151 | Apr 1994 | JP |
Number | Date | Country | |
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20060016427 A1 | Jan 2006 | US |