The present invention relates to an engine starting device and an engine starting method for an automatic idle-stop system for performing an engine idle stop when a predetermined idle-stop condition is satisfied and restarting the engine when a restart condition is thereafter satisfied.
Hitherto, for the purposes of improving fuel efficiency and reducing an environmental load of automobiles, and for other such purposes, there have been developed automatic idle-stop systems for automatically performing an idle stop with the satisfaction of a predetermined condition. However, it takes time for the engine rotation to be completely stopped by a friction force, and a conventional idle-stop system cannot carry out the restart during this period.
Thus, as a method for solving this problem, for example, there is a method involving, in a start control device for an internal combustion engine, when start rpm determination means determines that the rpm of the internal combustion engine decreases to an rpm enabling engagement of a rotation drive mechanism with the internal combustion engine, engaging the rotation drive mechanism with the internal combustion engine, thereby rotationally driving the internal combustion engine (for example, refer to PTL 1).
Moreover, there is an engine automatic stop/start control device including a starter capable of individually actuating a motor for rotationally driving a pinion, and an actuator for causing the pinion to mesh with a ring gear coupled to a crankshaft of an engine. If, in an engine rotation decreasing period in which the engine rpm decreases due to an automatic stop of the engine, an engine restart request is generated when the engine rpm is in a predetermined rpm area, after or while the engine automatic stop/start control device causes or is causing the pinion to mesh with the ring gear by the actuator, the engine automatic stop/start control device rotates the pinion by the motor, thereby starting cranking by the starter, and restarts the engine (for example, refer to PTL 2).
Moreover, there is known an engine starting device for carrying out determination processing of determining, when a restart request for an engine occurs, whether or not an engine rpm is equal to or lower than a predetermined meshing enabling rpm, first electric power supply processing of supplying a solenoid with electric power when the determination processing determines that the engine rpm is equal to or lower than the meshing enabling rpm, condition determination processing of determining whether or not a predetermined condition is established after the first electric power supply processing, and second electric power supply processing of supplying the starter motor with electric power when the condition determination processing determines that the condition is established (for example, refer to PTL 3).
However, the conventional technologies have the following problems.
According to PTL 1, the engine can surely be restarted earlier than in a case where complete stop of the engine is waited for, and the engine is restarted by causing the pinion gear and the ring gear to mesh with each other. However, generally, the engine repeats a forward rotation and a backward rotation around 0 rpm during an inertial rotation, and when the engine is rotating backward, the pinion gear possibly meshes with the ring gear.
Moreover, according to PTL 2, the restart of the engine can also be realized earlier than in the case where complete stop of the engine is waited for. However, PTL 2 does not mention anything about meshing during the backward rotation. Moreover, though there is a description of meshing by the actuator with the pinion gear before the backward rotation, a structure for individually operating the motor and the actuator is prerequisite. Therefore, there arises such a problem that the number of components, dimensions, the weight, and the like increase compared with those of conventional starters.
Moreover, the meshing is carried out each time the engine stops, and hence a meshing noise is generated independently of an operation by a driver, which may make the driver feel a sense of discomfort.
Moreover, in the device according to PTL 3, the meshing is not inhibited during the backward rotation of the engine, and such a structure that the motor and the actuator are individually operated is assumed. Moreover, this solution cannot be applied to a starter in which the movement of the pinion gear and the rotation of the starter motor cannot be individually carried out, and it is thus necessary to more precisely estimate the backward rotation behavior of the engine.
Moreover, for example, such setting is considered that, when the meshing is inhibited during the backward rotation, if the engine rpm reaches an rpm lower than a predetermined rpm (on a minus side with respect to the predetermined rpm) and then again increases to an rpm equal to or higher than the predetermined rpm, the inhibition of the meshing is released. In this case, if an amount of the backward rotation is large, after the inhibition of meshing, the engine rpm decreases to an rpm lower than the predetermined rpm and then again increases to an rpm equal to or higher than the predetermined rpm, the inhibition of meshing is released, but if the amount of the backward rotation is small, after the inhibition of meshing, the engine rpm does not decrease to an rpm lower than the predetermined rpm, and the inhibition of meshing cannot be released. Therefore, only the comparison between the engine rpm and the predetermined rpm may not release the inhibition of meshing.
The present invention has been devised to solve the above-mentioned problems, and has an object to provide an engine starting device and an engine starting method capable of restraining an impact between a pinion gear and a ring gear during meshing, thereby quickly and quietly restarting an engine during an inertial rotation in an automatic idle-stop system.
According to the present invention, there is provided an engine starting device for an automatic idle-stop system for carrying out an idle-stop of an engine when a predetermined idle-stop condition is established, and then restarting the engine when a restart condition is established, the engine starting device including: a starter; a ring gear to be coupled to a crankshaft of the engine; a starter motor for starting the engine; a pinion gear for transmitting a rotation of the starter motor to the ring gear; and starter control means for causing, when the restart condition for the engine is established during a period in which a meshing permission condition for the ring gear and the pinion gear is established, the pinion gear and the ring gear to mesh with each other, thereby restarting the engine, and for inhibiting, when the restart condition is established during a period in which a meshing inhibition condition for the ring gear and the pinion gear is established, the meshing of the pinion gear and the ring gear so that the meshing of the pinion gear and the ring gear is prevented from occurring outside a meshing permissible range, and after the meshing inhibition condition is released, causing the pinion gear and the ring gear to mesh with each other, thereby restarting the engine, in which the starter control means determines the meshing permission condition and the meshing inhibition condition based on at least an engine rpm, and determines the release of the meshing inhibition condition before the engine completely stops based on at least one of the engine rpm and an elapsed time after the establishment of the meshing inhibition condition.
Further, according to the present invention, there is provided an engine starting method for an automatic idle-stop system for carrying out an idle-stop of an engine when a predetermined idle-stop condition is established, and then restarting the engine when a restart condition is established, the engine starting method being applied to an engine starting device including: a starter; a ring gear to be coupled to a crankshaft of the engine; a starter motor for starting the engine; a pinion gear for transmitting a rotation of the starter motor to the ring gear; and starter control means for causing, when the restart condition for the engine is established during a period in which a meshing permission condition for the ring gear and the pinion gear is established, the pinion gear and the ring gear to mesh with each other, thereby restarting the engine, and for inhibiting, when the restart condition is established during a period in which a meshing inhibition condition for the ring gear and the pinion gear is established, the meshing of the pinion gear and the ring gear so that the meshing of the pinion gear and the ring gear is prevented from occurring outside a meshing permissible range, and after the meshing inhibition condition is released, causing the pinion gear and the ring gear to mesh with each other, thereby restarting the engine, the engine starting method including: determining, by the starter control means, the meshing permission condition and the meshing inhibition condition based on at least an engine rpm; and determining, by the starter control means, the release of the meshing inhibition condition before the engine completely stops based on at least one of the engine rpm and an elapsed time after the establishment of the meshing inhibition condition.
According to the present invention, it is possible to provide the engine starting device and the engine starting method capable of restraining the impact between the pinion gear and the ring gear during the meshing by determining the meshing permission condition and the meshing inhibition condition based on at least the engine rpm, and determining the release of the meshing inhibition condition based on at least one of the engine rpm and the elapsed time after the establishment of the meshing inhibition condition, thereby quickly and quietly restarting the engine during the inertial rotation in the automatic idle-stop system.
Referring to the drawings, a description is now given of an engine starting device and an engine starting method for a four-cylinder engine, as an example, according to preferred embodiments of the present invention.
The engine starting device 10 according to this embodiment illustrated in
The starter control means 11 controls power supply to the solenoid 18. The power supply to the solenoid 18 results in the attraction of the plunger 17, thereby moving the pinion gear 15 via a lever 19 (refer to
Moreover, the ring gear 12 meshes with the pinion gear 15, thereby transmitting a drive force to the engine. Moreover, the crank angle sensor 13 detects a crank angle of the engine. Moreover, the one-way clutch 16 is coupled to an output shaft of the starter motor 14, and freely rotates if a torque is input from the ring gear 12.
Then, the starter control means 11 can calculate an engine rpm based on a cycle of a rotation pulse of the crankshaft output from the crank angle sensor 13.
A description is now given of an engine inertial rotation behavior when an idle-stop condition is established in the engine starting device according to the first embodiment.
When an automatic stop condition (for example, such a condition that a vehicle speed is equal to or lower than 15 km/h, and the driver is depressing a brake) is established during a travel of a vehicle, the fuel supply to the engine is stopped, thereby bringing the engine into an inertial rotation state.
The present invention has a technical feature in that, when a restart condition is established and the engine rpm is outside a meshing permissible range represented by the broken lines of
Referring to
On the other hand, when the starter control means 11 determines that the idle stop condition is established in Step S110, the processing proceeds to Step S111, and the starter control means 11 carries out engine stop control. Specifically, the starter control means 11 stops the fuel supply to the engine, and reduces the rpm by means of the inertial rotation.
Then, in Step S112, the starter control means 11 determines whether or not the engine is completely stopped. The determination as to whether or not the engine is completely stopped is made by whether or not a pulse for the crank angle is detected for a predetermined period (such as 300 ms). Thus, when the pulse for the crank angle is not detected for the predetermined period, the starter control means 11 determines that the engine is completely stopped, finishes the processing, and proceeds to the next cycle.
On the other hand, in Step S112, when the starter control means 11 determines that the engine is not stopped completely, the processing proceeds to Step S113, and the starter control means 11 determines whether or not the restart condition is established.
When the starter control means 11 determines that the restart condition is established, the processing proceeds to Step S114, and the starter control means 11 carries out engine restart control. On the other hand, when the starter control means 11 determines that the restart condition is not established, the processing returns to Step S112.
Now, a detailed description is given of the engine restart control in Step S114.
First, in Step S210, the starter control means 11 determines whether or not the meshing inhibition condition is established. On this occasion, the establishment of the meshing inhibition condition is determined by whether or not an engine rpm NE when the power is fed to the solenoid 18 and the pinion gear 15 meshes with the ring gear 12 is equal to or lower than a second predetermined rpm N2.
A description is now given of the meshing of the pinion gear 15 and the ring gear 12 with each other. If a difference in rpm between the pinion gear 15 and the ring gear 12 is large, an impact and a noise are generated during the meshing, and the pinion gear 15 and the ring gear 12 thus need to mesh with each other in an rpm difference range (−150 rpm to 150 rpm) prescribed by an upper limit rpm of meshing permissible range (such as 150 rpm) and a lower limit rpm of meshing permissible range (such as −150 rpm).
Moreover, the meshing of the pinion gear 15 and the ring gear 12 with each other as a result of the power supply to the solenoid 18 generates a delay time Td (such as 10 ms) from the start of the power supply to the solenoid 18 to the completion of the meshing, and it is thus necessary to consider the delay time in meshing the gears with each other. Therefore, the second predetermined rpm N2 is set by considering the above-mentioned condition. Specifically, the second predetermined rpm N2 is an engine rpm the delay time Td before a time when the engine rpm reaches the lower limit rpm of meshing permissible range.
This setting enables to start the power supply to the solenoid 18 at an engine rpm higher than the second predetermined rpm N2, and when the meshing occurs after the delay time Td has elapsed, the engine rpm reaches an rpm equal to or higher than the lower limit rpm of permissible range, and hence smooth meshing is realized.
If the meshing starts at an rpm equal to or lower than the second predetermined rpm N2, the rpm when the gears actually mesh with each other is outside the permissible range, an impact torque and a noise corresponding to the rpm are generated, and the lifetime of the starter may be decreased, which are not preferred.
Thus, in Step S210, when the starter control means 11 determines that the engine rpm NE is higher than the second predetermined rpm, the processing proceeds to Step S211, and the starter control means 11 determines whether or not the meshing permission condition is established.
On this occasion, the establishment of the meshing permission condition is determined by whether or not the engine rpm NE is equal to or lower than the first predetermined rpm N1 (provided that N1>N2). When the starter control means 11 determines that the meshing permission condition is established (NE≦N1), the processing proceeds to Step S213, and the starter control means 11 supplies the solenoid 18 with electric power, thereby causing the pinion gear 15 and the ring gear 12 to mesh with each other.
On this occasion, the first predetermined rpm N1 is set by considering the upper limit rpm of meshing permissible range (such as 150 rpm) and the delay time Td. Specifically, the first predetermined rpm N1 is an engine rpm the delay time Td before a time when the engine rpm reaches the upper limit rpm of meshing permissible range. This setting enables to start the power supply to the solenoid 18 at an engine rpm equal to or lower than the first predetermined rpm N1, and when the meshing occurs after the delay time Td has elapsed, the engine rpm is equal to or lower than the upper limit rpm of permissible range, and hence smooth meshing is realized.
Moreover, in Step S211, when the engine rpm NE is higher than the first predetermined rpm N1, the starter control means 11 waits until the engine rpm NE decreases by friction to an rpm equal to or lower than N1, and then the processing proceeds to Step S213.
Moreover, when the engine rpm NE is equal to or lower than the second predetermined rpm N2 in Step S210 described above, the processing proceeds to Step S212.
Then, in Step S212, the starter control means 11 determines whether or not to release the meshing inhibition condition depending on whether or not an elapsed time T after the meshing inhibition condition is established (NE≦N2) is longer than a predetermined time T1. On this occasion, the predetermined time T1 is set to a time when the backward rotation of the engine ends, or the engine rpm falls within the rpm range sufficient for the meshing.
Referring to
Moreover, the elapsed time T is an elapsed time after the engine rpm NE reaches an rpm equal to or lower than the predetermined rpm N2 irrespective of whether or not the restart condition is established. Then, when the starter control means 11 determines that the elapsed time T after the meshing inhibition condition is established is longer than the predetermined time T1, the starter control means 11 releases the establishment of the meshing inhibition condition, and the processing proceeds to Step S213.
Then, in Step S213, the starter control means 11 supplies the solenoid 18 with electric power, thereby causing the pinion gear 15 and the ring gear 12 to mesh with each other. As a result, the meshing of gears with each other at an rpm outside the meshing permissible range during the backward rotation of the engine can surely be avoided, to thereby realize quiet and smooth meshing of the gears.
Then, the processing proceeds to Step S214, and the starter control means 11 causes the pinion gear 15 and the ring gear 12 to mesh with each other, and then restarts the engine by cranking.
As described above, the engine starting device according to the first embodiment determines, based on at least the engine rpm, whether or not the meshing permission condition and the meshing inhibition condition are established, and further determines whether or not to release the establishment of the meshing inhibition condition based on the elapsed time after the inhibition condition is established.
As a result, the meshing of the pinion gear and the ring gear with each other can be carried out quickly and surely, and hence the meshing of the gears can be carried out within the meshing permissible range without making the driver feel a sense of discomfort, and the reduction in noise and restraint of the impact torque at the time of the meshing of the pinion gear and the ring gear with each other, and an increase in lifetime of components can be attained.
Note that, according to the first embodiment described above, the meshing inhibition condition is established when the engine rpm NE reaches an rpm equal to or lower than the second predetermined rpm N2, but the establishment of the inhibition condition is not limited to this case. When the meshing inhibition condition is once established, and the establishment of the inhibition condition is released after the predetermined time T1 has elapsed, the engine restarts, and the inhibition condition may be prevented from being established until the next idle-stop.
This is because second and later backward rotation amounts are small, and this control can prevent the meshing inhibition condition from being established when the engine rotates backward once and then rotates forward, and the engine rpm NE decreases again to an rpm equal to or lower than the second predetermined rpm N2. As a result, unnecessary meshing inhibition can be prevented, and a quick restart of the engine can be realized.
Moreover, generally, the engine rpm is often calculated based on the cycle of a pulse generated each time the engine rotates by a predetermined crank angle, but the engine rpm may be calculated by considering a period in which the pulse of the each crank angle is not present as well.
The calculation method based only on the crank angle pulse does not update the engine rpm while the crank angle pulse is not present, and there is a case where a delay is generated with respect to the actual engine rpm. In contrast, by considering the period in which the crank angle pulse is not present as well, the release of the meshing inhibition can be determined based on an engine rpm corresponding to the actual engine rpm.
Moreover, in the above-mentioned first embodiment, a description has been given of the starter (corresponding to a widely prevailing single solenoid type starter) operationally associating the power supply to the solenoid 18 and the power supply to the starter motor 14 with each other as an example. The engine starting method according to the present invention can be applied to this starter, and does not require changes in engine layout and changes in manufacturing line.
However, the application of the present invention is not limited to this starter, and the present invention can be applied to a starter which can independently control the power supply to the solenoid and the power supply to the starter motor, and the above-mentioned effects can be acquired also in this case.
In the above-mentioned first embodiment, the first predetermined rpm N1 and the second predetermined rpm N2 are set as constant rpms. However, these predetermined rpms are not necessarily constant values, and the values may be set for each crank angle depending on engine pulsation, for example.
Thus, according to a second embodiment, referring to
During the inertial rotation of the engine, before and after the compression top dead center, the compression stroke and the expansion stroke are switched, and hence the sign of a rotational acceleration is inverted. Thus, as shown in
Thus, as shown in
In this way, according to the second embodiment, there may be provided control of changing the first predetermined rpm N1 depending on the crank angle, thereby supplying the solenoid 18 with the electric power so that the engine rpm NE when the pinion gear 15 meshes with the ring gear 12 surely falls within the meshing permissible range.
A description is now given of a case where the second predetermined rpm N2 is changed depending on the crank angle.
As described above, during the inertial rotation of the engine, before and after the compression top dead center, the compression stroke and the expansion stroke are switched. Therefore, as shown in
Thus, as shown in
In this way, according to the second embodiment, there may be provided control of changing the second predetermined rpm N2 depending on the crank angle, thereby surely inhibiting the meshing in the case where the engine rpm NE at a time when the solenoid 18 is supplied with the electric power so as to cause the pinion gear 15 to mesh with the ring gear 12 is equal to or lower than the meshing permissible range.
Referring to a flowchart illustrated in
When the restart condition is established, the processing proceeds to Step S310, and the starter control means 11 compares the engine rpm NE and the second predetermined rpm N2 with each other. Then, when NE is equal to or lower than N2, the processing proceeds to Step S314, and when NE is higher than N2, the processing proceeds to Step S312.
On this occasion, the second predetermined rpm N2 is set in Step S311. Specifically, a table on which the corresponding value of N2 is set for each crank angle of the engine is stored in advance, and an appropriate value is set as N2 depending on the crank angle of the engine in the control cycle.
As a result, as described above, when the compression and expansion are repeated due to a change in crank angle, and the engine rpm decreases while presenting pulsation, the meshing inhibition condition can be prevented from being established in an unintended period (corresponding to the above-mentioned times tg to th of
In Step S310, when the starter control means 11 determines that NE≦N2, as in the case where the starter control means 11 determines that NE≦N2 in Step S210 of
Moreover, in Step S310, when the starter control means 11 determines that NE>N2, the processing proceeds to Step S312. On this occasion, the first predetermined rpm N1 is set in Step S313. Specifically, as in N2, a table on which the corresponding value of N1 is set for each crank angle of the engine is stored in advance, and an appropriate value is set as N1 depending on the crank angle of the engine in the control cycle.
As a result, as described above, when the compression and expansion are repeated due to a change in crank angle, and the engine rpm decreases while presenting pulsation, the meshing permission condition can be prevented from being established at an unintended timing (corresponding to the times tc to td of
In Step S312, when the starter control means 11 determines that NE≦N1, the processing proceeds to Step S315, and the starter control means 11 supplies the solenoid 18 with the electric power, thereby causing the pinion gear 15 to mesh with the ring gear 12. Then, the processing proceeds to Step S316, and the starter control means 11 restarts the engine by cranking.
As described above, the engine starting device according to the second embodiment can carry out, by changing N1 and N2 depending on the crank angle, the meshing permission at appropriate timings and the meshing inhibition in appropriate periods.
According to the second embodiment described above, a description has been given of the case where both N1 and N2 are changed depending on the crank angle, but both of N1 and N2 are not necessarily changed, and any one of N1 and N2 may be changed.
In the above-mentioned first and second embodiments, a description has been given of the case where the release of the meshing inhibition condition is determined based on whether or not the elapsed time T after the meshing inhibition condition is established is longer than the predetermined time T1. In contrast, according to a third embodiment, a description is given of a case where whether or not to release the meshing inhibition condition is determined based on the engine rpm.
When the meshing inhibition condition has not been established even once at this time point, the meshing inhibition condition may be prevented from being established during the inertial rotation by the idle-stop.
Then, referring to a flowchart illustrated in
When respective Steps S310 to S316 illustrated in the flowchart of
When the restart condition is established, the processing proceeds to Step S410, and the starter control means 11 compares the engine rpm NE and the second predetermined rpm N2 with each other. Then, when NE is equal to or lower than N2, the processing proceeds to Step S414, and when NE is higher than N2, the processing proceeds to Step S412.
On this occasion, when the processing proceeds to Step S412, the same control as that in the case where the processing proceeds to Step S312 in
In Step S414, the starter control means 11 determines whether or not an engine rpm change rate dNE is larger than 0. When the starter control means 11 determines that dNE>0, the starter control means 11 determines that the peak of the backward rotation has passed and releases the meshing inhibition condition, and the processing proceeds to Step S415. Then, the starter control means 11 supplies the solenoid 18 with the electric power, thereby causing the pinion gear 15 and the ring gear 12 to mesh with each other, and in Step S416, restarts the engine by cranking.
On this occasion, the engine rpm change rate dNE may be calculated based, for example, on a previous value and a current value at an update timing of the engine rpm NE, or on a moving average of a plurality of pieces of data.
In this way, in Step S414, when the starter control means 11 releases the meshing inhibition by determining whether or not the peak of the backward rotation has passed, in Step S415, the starter control means 11 supplies the solenoid 18 with the electric power, and at the time when the pinion gear 15 meshes with the ring gear 12, the engine rpm NE has already increased to an engine rpm within the meshing permissible range. Therefore, smooth meshing can be carried out.
As described above, the engine starting device according to the third embodiment can release the meshing inhibition condition by determining whether or not the peak of the backward rotation has passed. As a result, the meshing inhibition does not need to be released based on the elapsed time T after the inhibition condition is established as described above in the above-mentioned first and second embodiments, and the meshing inhibition can be released based on the engine rotation behavior.
In the above description of the third embodiment, the release of the meshing inhibition is determined based only on the condition that the peak of the backward rotation has passed or not, but the release of the meshing inhibition may be determined in consideration of the engine rpm in addition to the change rate of the engine rpm.
By means of this determination, when the engine rpm NE falls within the meshing permissible range at the peak of the backward rotation where the change rate of the engine rpm changes from a negative value to a positive value, the engine rpm does not decrease or depart from the meshing permissible range, and hence the meshing inhibition may be released.
Conversely, when the engine rotation speed NE is outside the meshing permissible range, the meshing inhibition is not released, and the meshing inhibition may be released at the time when the predetermined time T1 has elapsed or when the engine rotation speed enters the meshing permissible range.
In this way, by considering both the engine rotation speed and the change rate of the engine rotation speed in the control cycle, the accuracy of the release of the meshing inhibition can be further increased.
Moreover, by considering the delay time after the power supply to the solenoid 18 is started until the pinion gear 15 meshes with the ring gear 12, and using the change rate of the engine rotation speed, the engine rotation speed when the delay time Td has elapsed is estimated, and when the estimated engine rotation speed enters the meshing permissible range, the meshing inhibition may be released. In this way, by considering the change rate of the engine rotation speed in the control cycle, the accuracy of the release of the meshing inhibition can be further increased.
Number | Date | Country | Kind |
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2011-187518 | Aug 2011 | JP | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/JP2012/068694 | 7/24/2012 | WO | 00 | 7/9/2013 |