Patent Application
20080081702
This application is based on Japanese Patent Application No. 2006-233281 filed on Aug. 30, 2006, the disclosure of which is incorporated herein by reference.
The present invention relates to a variable valve timing controller which includes an electric motor as a driving source. A rotation speed of the electric motor is varied to adjust a rotational phase of the camshaft relative to a crankshaft, whereby a valve timing of an intake valve and/or an exhaust valve of an internal combustion engine is adjusted.
In order to perform electronic control of the variable valve timing control, the variable valve timing controller which has the motor as a source of the drive has been developed. The variable valve timing controller described in JP-2006-70754A (US2006/0042578A1) includes a first gear, a second gear, a phase changing gear, and an electric motor. The first gear (outer gear) is concentrically arranged with the camshaft and is rotated with the rotation driving force of the crankshaft. The second gear (inner gear) rotates together with the camshaft. The phase changing gear (planet gear) transmits the torque of the first gear to the second gear, and varies the rotational phase of the second gear relative to the first gear. The motor is coaxially provided to the camshaft so that the revolution speed of the phase changing gear is controlled. The number of teeth of the first gear, the second gear, and the phase changing gear is determined so that the camshaft may rotate with one half of the rotational speed of the rotational speed of the crankshaft.
In the above motor drive variable valve timing controller, as a driving current of the motor (“motor current”) increases during the variable valve timing control, the heat value of the motor increases and a coil temperature rises. When the transient operating condition in which a target motor speed (target valve timing) changes frequently continues, a coil temperature of the motor may exceed an allowable temperature and will cause durability deterioration and malfunction of the motor.
The present invention is made in view of the above matters, and it is an object of the present invention to provide a variable valve timing controller which adjusts valve timing by use of an electric motor and is able to restrict an excessive temperature rising of a motor coil.
According to the present invention, a variable valve timing controller adjusting a valve timing of an intake valve and/or an exhaust valve by varies a speed of an electric motor relative to a rotational speed of a camshaft in such a manner as to vary a camshaft phase representing a rotational phase of the camshaft relative to a crankshaft of an internal combustion engine. The controller includes a target motor speed computing means for computing a target motor speed based on a rotation speed of the internal combustion engine and a deviation between a target camshaft phase and an actual camshaft phase. The controller includes a motor drive control means for feedback controlling a motor current representing a driving current of the motor in such a manner as to decrease a deviation between the target motor speed and an actual motor speed. The controller includes a motor current estimating means for estimating the motor current, and a motor current restricting means for restricting the motor current when the motor current estimated by the motor current estimating means exceeds a predetermined value.
Hence, the heat value of motor may not exceed the heat generation limit, and it can be prevented that the coil temperature of motor exceeds the allowable temperature range. The durability deterioration and failure of motor can be prevented. In this case, when the motor current is restricted, the speed of response of the variable valve timing control becomes slow.
Embodiments of the present invention will be described hereinafter.
Referring to FIGS. 1 to 9, a first embodiment 1 of the present invention is described hereinafter.
A cam angle sensor 19 is provided around the intake camshaft 16. The cam angle sensor 19 outputs a cam angle signal every predetermined cam angle of the intake camshaft 16. A crank angle sensor 20 is provided around the cranks shaft 12. The crank angle sensor 20 outputs a crank angle signal every predetermined crank angle.
Referring to
The variable valve timing controller 18 includes a phase control mechanism 21. The phase control mechanism 21 includes an outer gear 22 (a first gear), an inner gear 23 (a second gear), and a planet gear 24 (a phase changing gear). The outer gear 22 is concentrically arranged with the intake camshaft 16 and has inner teeth. The inner gear 23 is concentrically arranged with the outer gear 22 and has outer teeth. The planet gear 24 is arranged between the outer gear 22 and the inner gear 23 to be engaged with both gears 22, 23. The outer gear 22 rotates integrally with the sprocket 14 which rotates in synchronization with the crankshaft 12, and the inner gear 23 rotates integrally with the intake camshaft 16. Engaging with the outer gear 22 and the inner gear 23, the planet gear 24 rotates around the inner gear 23 to transfer a rotation force from the outer gear 22 to the inner gear 23. A rotational phase of the inner gear 23 (camshaft phase) relative to the outer gar 22 is adjusted by varying a revolution speed of the planet gear 24 relative to the rotation speed of the inner gear 23. The number of teeth of the outer gear 22, the inner gear 23 and the planet gear 24 are determined in such a manner that the intake camshaft 16 rotates in a half speed of the crankshaft 12.
Rotational speed of the intake camshaft 16=Rotational speed of the crankshaft 12×½
The engine 11 is provided with a motor 26 which varies the revolution speed of the planet gear 24. A rotation shaft 27 of the motor 26 is concentrically arranged with the intake camshaft 16, the outer gear 22, and the inner gear 23. A connecting shaft 28 connects the rotation shaft 27 with a supporting shaft 25 of the planet gear 24. When the motor 26 is energized, the planet gear 24 rotates on the supporting shaft 25 and orbits around the inner gear 23. Besides, the motor 26 is provided with a motor speed sensor 29 which outputs a rotational motor speed signal.
When the motor 26 is not energized, the rotation shaft 27 rotates in synchronization with the intake camshaft 16. That is, when the rotation speed RM of the motor 26 is consistent with the rotation speed RC of the intake camshaft 16, and the revolution speed of the planet gear 24 is consistent with the rotational speed of the inner gear 23, a difference between a rotational phase of the outer gear 22 and a rotational phase of the inner gear 23 is maintained as a current difference to maintain the valve timing (camshaft phase) as the current valve timing.
When the rotation speed RM of the motor 26 is made higher than the rotational speed RC of the intake camshaft 16, that is, when the revolution speed of the planet gear 24 is made higher than the rotational speed of the inner gear 23, the rotational phase of the inner gear 23 relative to the outer gear 22 is advanced so that the valve timing of the intake valve is advanced. Thereby, the rotational phase of the inner gear 23 relative to the outer gear 22 is advanced, and the valve timing (camshaft phase) is advanced.
Meanwhile, When the rotation speed RM of the motor 26 is made lower than the rotational speed RC of the intake camshaft 16, that is, when the revolution speed of the planet gear 24 is made lower than the rotational speed of the inner gear 23, the rotational phase of the inner gear 23 relative to the outer gear 22 is retarded so that the valve timing of the intake valve is retarded.
The outputs of the sensors are inputted into an electronic control unit 30, which is referred to as an ECU 30 hereinafter. The ECU 30 includes a microcomputer which executes engine control programs stored in a ROM (read only memory) to control a fuel injection and an ignition timing according to an engine driving condition.
Moreover, the ECU30 calculates a rotational phase (actual camshaft phase) of the camshaft 16 relative to the crankshaft 12 based on the output of the cam angle sensor 19 and the crank angle sensor20. The ECU30 calculates the target camshaft phase (target valve timing) according to an engine operating conditions. The ECU30 calculates the target motor speed based on the engine speed and a deviation between the target camshaft phase and the actual camshaft phase. And as shown in
The EDU31 performs a motor drive control. The EDU31 has an analog rotating-speed feedback circuit 32 which performs feedback control of the duty of the voltage applied to the motor 26 so that the deviation of the target motor speed and an actual motor speed is decreased. The EDU31 performs a feedback control of the actual motor speed to the target motor speed, and performs a feedback control of the actual camshaft phase to the target camshaft phase. “Feedback” is expressed as “F/B” in the following description.
The ECU30 is executing each program shown in
[Target Motor Speed Computation Program]
The ECU30 executes the target motor speed computation program shown in
In step 101, a deviation between the target camshaft phase and the actual camshaft phase is computed. This deviation is referred to as the camshaft phase deviation.
Camshaft phase deviation (CPD)=Target camshaft phase (TCP)−Actual camshaft phase (ACP)
Then, the procedure proceeds to step 102 in which the rotational speed F/B correction amount according to the present engine speed and the camshaft phase deviation is computed with reference to the rotational speed F/B correction amount map shown in
After computing the rotational speed F/B correction amount, the procedure proceeds to step 103 in which a motor current estimation program shown in
Target motor speed (TMS)=Base target motor speed (BTMS)+Motor speed F/B correction amount (MSFBC)
Here, the base target motor speed is the motor speed which is in agreement with the camshaft rotational speed (crankshaft rotation speed×½).
When the answer is Yes in step 104, the procedure proceeds to step 105 in which an upper guard value and a lower guard value are computed based on the instant engine speed according to an upper-lower guard value map shown in
Then, the procedure proceeds to step 106 in which the motor speed F/B amount computed in step 102 is guard-processed by using of the upper and lower guard values computed in step 105. That is, in a case that the motor speed F/B correction amount is greater than the upper guard value, the motor speed F/B correction amount is brought to the upper guard value. In a case that the motor speed F/B correction amount is less than the lower guard value, the motor speed F/B correction amount is brought to the lower guard value. In a case that the motor speed F/B correction amount is within a range between the upper guard value and the lower guard value, the motor speed F/B correction amount is not changed. In steps 105, and 106, electric current applied to the motor is restricted.
Then, the procedure proceeds to step 107 in which the target motor speed is computed by using of the guard-processed rotational speed F/B correction amount.
Target motor speed (TMS)=Base target motor speed (BTMS)+Guard-processed motor speed F/B correction amount (G-MSFBC)
The ECU30 outputs the signal indicative of the target motor speed calculated by the above process toward the EDU31.
[Motor Current Estimation Program]
The motor current estimation program shown in
When the answer is No, the procedure proceeds to step 203 in which it is determined whether a most retard control is executed. In the most retard control, the camshaft phase is fixed at the most retarded phase (reference phase). When the answer is Yes in step 203, the procedure proceeds to step 204 in which an indication current is set as an estimation motor current. The indication current is a motor current which is determined based on an indication duty at the most retard control.
Meanwhile, when the answer is No in step 203, the procedure proceeds to step 205 in which the deviation between the target motor speed and the actual motor speed is multiplied by a F/B gain G to obtain the motor speed F/B amount.
Motor speed F/B amount=G×(Target motor speed−Actual motor speed)
Then, the procedure proceeds to step 206 in which the motor speed F/B amount computed in step 205 is added to the target motor speed to obtain a motor control mount.
Motor control amount=Target motor speed+Motor speed F/B amount
Then, the procedure proceeds to step 207 in which the instant motor control amount and the estimated motor current according to the engine speed are computed with reference to an estimated motor current map shown in
Besides, the estimated motor current may be computed based on a map which has the target motor speed, the actual motor speed, and the engine speed as parameters. Alternatively, the estimated motor current may be computed based on a map which has the target motor speed and the actual motor speed as parameters. The estimated motor current may be computed by taking into consideration the parameters (for example, battery voltage, camshaft phase deviation) other than the above.
A control process of the first embodiment will be described hereinafter based on time charts shown in
Since the estimated motor current is less than a threshold equivalent to the heat generation limiting current value before time t1, the guard process to motor speed F/B amount is not performed. Then, when estimated motor current exceeds the threshold at time t1, the guard process to the motor speed F/B amount is started. The motor speed F/B amount is restricted with the upper limit guard value and the lower limit guard value. Thereby, the variation (motor speed F/B amount) in target motor speed outputted to EDU31 is restricted, and the motor current is restricted.
Then, at time t2, when the estimated motor current falls to less than the threshold, the guard process to motor speed F/B amount is canceled. In this state, the motor speed F/B amount is not limited within the range between the upper limit guard value and the lower limit guard value, it may be established outside the range. The actual motor speed (actual camshaft phase) is changed according to a change in target motor speed (target camshaft phase) with high response.
According to the first embodiment, the motor current is estimated based on the target motor speed, the actual motor speed, and the engine speed. When the estimated motor current exceeds the predetermined value (threshold) equivalent to the heat limiting current value, the variation (motor speed F/B amount) in the target motor speed outputted to the EDU31 from the ECU30 is restricted, and the motor current is also restricted. Hence, the heat value of motor 26 may not exceed the heat generation limit, and it can be prevented that the coil temperature of motor 26 exceeds the allowable temperature range. The durability deterioration and failure of motor 26 can be prevented. In this case, when the motor current is restricted, speed of response only becomes slow and the variable valve timing control can be performed to reduce the deviation of the target camshaft phase and the actual camshaft phase.
In a second embodiment shown in
In the target motor speed computation program shown in
After computing the camshaft phase deviation and the rotational speed F/B correction amount in steps 101 and 102, the procedure proceeds to step 103a in which a duty estimation program shown in
When the answer is Yes in step 104a, the procedure proceeds to step 105 in which an upper guard value and a lower guard value are computed based on the instant engine speed according to a upper-lower guard value map shown in
In the duty ratio estimation program shown in
When the answer is No in step 201 and the answer is Yes in step 203, the procedure proceeds to step 204a in which an indication duty of the most retarded control is set as the estimated duty.
When the answers are No in steps 201 and 203, the procedure proceeds to steps 205 and 206 to compute the motor control amount. Then, the procedure proceeds to step 207a in which an estimated duty ratio according to the motor control amount is computed based on a map.
In the second embodiment, the duty of the voltage applied to motor 26 is estimated as the information of the motor current, and when the estimated duty exceeds the predetermined value, the variation (motor speed F/B correction amount) in the target motor speed which is outputted to the EDU31 from the ECU30 is restricted, whereby the motor current is restricted. Therefore, the same advantage as first embodiment can be obtained.
In first and second embodiments, when the estimated motor current (duty) exceeded the specified value, the motor current is restricted. In a third embodiment shown in
According to the third embodiment, when the estimated current (duty) exceeds the specified value, the motor current is intercepted to decrease coil temperature of the motor 26. Furthermore, since the diagnosis of variable valve timing controller 18 is stopped, it can prevent an erroneous decision that the state where the variable valve timing control is compulsorily stopped by interception of the motor current is determined as malfunction.
Besides, the present invention is not limited to the variable valve timing controller of the intake valve, but may be applied to the variable valve timing controller of the exhaust valve. Furthermore, the phase variable mechanism of the variable valve timing device 18 is not limited to the planetary gear mechanism. Other mechanisms are employable when the valve timing is changed by varying the rotational speed of the motor relative to the rotational speed of the camshaft.
| Number | Date | Country | Kind |
|---|---|---|---|
| 2006-233281 | Aug 2006 | JP | national |
