JP5910476B2 - Engine starter - Google Patents

Description

  The present invention is applied to a vehicle that performs idling stop when a predetermined engine stop condition is satisfied, and responds to the restart request when a restart request is generated during inertial rotation until the engine stops. The present invention relates to an engine starter that restarts the engine.

In recent years, vehicle idling stop technology has become an important means as one of the CO2 reduction measures in global warming countermeasures. This idling stop technology is a system that automatically stops the engine by cutting fuel injection into the engine when the vehicle is temporarily stopped due to traffic lights on intersections or traffic jams on the road. It is effective for improvement.
In order to widely disseminate this idling stop technology, it is necessary to improve engine startability. In other words, even during inertial rotation of the engine, when the start operation by the driver (for example, release operation of the brake pedal, shift operation to the drive range, etc.) is performed and an engine restart request is generated, the engine is operated as quickly as possible. It is required to restart.

By the way, a starter of a type in which a pinion jumps into an engine ring gear (hereinafter referred to as a jump-in starter) is generally used in a state where the ring gear of the engine is stopped. Therefore, when the dive starter is operated during inertial rotation of the engine, the pinion collides with the rotating ring gear, and an excessive impact is applied to the pinion. For this reason, the pinion and the ring gear may be worn out, or the pinion and the ring gear may be damaged.
On the other hand, Patent Document 1 discloses a technique in which, for example, the drive motor is switched on when the engine is stopped and the peripheral speed between the ring gear and the pinion is made sufficiently close, and then the pinion is engaged with the ring gear. As a result, the engine can be restarted even during inertial rotation of the engine.

Special table 2009-529114 gazette

In the prior art according to Patent Document 1 described above, after the drive motor switch is turned on, the drive motor switch is temporarily turned off when the rotational speed of the pinion reaches a predetermined threshold value. That is, after the drive motor switch is turned off, the pinion is pushed out and meshed with the ring gear when the peripheral speed difference between the ring gear and the pinion is suitable for meshing. For this reason, in order to restart the engine, it is necessary to turn on the drive motor again after the pinion is engaged with the ring gear.
By the way, since an excessive current is often passed through the starter motor in order to obtain a torque necessary for starting the engine, an arc may be generated between the contacts when the drive motor is switched off. For this reason, if the drive motor is turned off and then turned on again within a short time, there is a concern that the contact life may be reduced due to arcing.

Therefore, in order to suppress a decrease in the contact life, it is necessary to take a predetermined interval after the drive motor switch is turned off and before it is turned on again. For this reason, when a restart request is generated during inertial rotation of the engine, it is necessary to wait for the engine to start until the interval elapses even if the ring gear and the pinion can be brought into close mesh with each other. It becomes impossible to start the engine quickly.
In general, in a starter that employs a commutator motor, a large current called a starting current or an inrush current flows when the motor is started, which affects brush wear. However, in Patent Document 1, the first motor energization is performed in order to make the peripheral speeds of the ring gear and the pinion closer, and the second motor energization is performed after the pinion meshes with the ring gear. That is, since the drive motor switch is turned on twice in one engine start, the inrush current flows twice in the drive motor, and there is a concern that the life of the brush may be reduced due to accelerated brush wear.

  The present invention has been made based on the above circumstances, and its purpose is to promptly restart the engine when a request for restarting the engine occurs even during inertial rotation of the engine due to idling stop. Another object of the present invention is to provide an engine starter that can prevent welding of a main contact that interrupts the energization current of a motor and that can suppress a decrease in life due to brush wear.

  The present invention is an engine starter that is applied to a vehicle that performs an idling stop for automatically stopping an engine when a predetermined engine stop condition is satisfied, and that restarts the engine when an engine restart request is generated. The starter that engages the pinion with the ring gear of the engine and transmits the rotational force generated in the motor from the pinion to the ring gear to start the engine, and the motor circuit for energizing the motor from the battery are provided with the motor drive voltage. A resistor for suppressing, a current bypass function for short-circuiting both ends of the resistor, an auxiliary switch for turning on / off the current bypass function according to excitation / de-excitation of a built-in coil, and operation of a starter and an auxiliary switch And a control device for controlling.

The starter forms an electromagnet by energization, and a pinion drive solenoid that pushes the pinion to the ring gear side by utilizing the attraction force of the electromagnet, and an electromagnet by energization, and is provided in the motor circuit by on / off control of the electromagnet When the control for turning off the current bypass function by energizing the auxiliary switch coil is called current bypass OFF, the control device stops the engine rotation due to idling stop. When the engine restart request occurs during inertial rotation until the pinion drive solenoid and the motor energization solenoid are individually controlled, at least before the pinion contacts the ring gear, the current bypass is turned off. Run to suppress motor drive voltage And wherein the door.
Furthermore, the control for energizing the pinion drive solenoid to push the pinion toward the ring gear is called pinion push-out control, and energization of the motor is started by energizing the motor energization solenoid and closing the main contact. The control device has first determination means for comparing the peripheral speed difference between the ring gear and the pinion with the first determination value in response to an engine restart request. When the determination result of the first determination means is the peripheral speed difference ≧ first determination value, the motor energization control is executed before the pinion push-out control and the current bypass OFF, and the determination result of the first determination means is When the speed difference <the first determination value, the pinion push-out control and the current bypass OFF are executed before the motor energization control.

Since the engine starter of the present invention can independently control the pinion drive solenoid and the motor energization solenoid, the rotation speed of the pinion can be made closer to the rotation speed of the ring gear. Therefore, even when a restart request is generated during inertial rotation of the engine, the pinion can be engaged with the rotating ring gear, and the engine can be restarted in a short time.
Further, at least before the pinion comes into contact with the ring gear, the current bypass OFF is executed, that is, the current bypass function of the auxiliary switch is turned off, so that the driving voltage of the motor is suppressed by the resistor.

According to the above control, since the increase in the rotation speed of the pinion can be suppressed with respect to the ring gear during inertial rotation, the pinion can be engaged with the ring gear while maintaining the peripheral speed difference between the pinion and the ring gear. As a result, it is possible to reduce the impact and sound generated when the pinion and the ring gear mesh with each other, and to reduce wear of the ring gear and the pinion.
In addition, by controlling the motor drive voltage by executing current bypass OFF, the large current (rush current) that flows when the motor is started can be suppressed, thus preventing welding of the main contact for intermittently supplying the motor current. it can.

1 is a configuration diagram of an engine starter according to Embodiment 1. FIG. 3 is a flowchart illustrating a processing procedure of the ECU according to the first embodiment. 3 is a time chart of idling stop control according to the first embodiment. 7 is a flowchart illustrating a processing procedure of an ECU according to a second embodiment. FIG. 6 is a configuration diagram of an engine starter according to a third embodiment. 7 is a flowchart illustrating a processing procedure of an ECU according to a third embodiment. 6 is a time chart of idling stop control according to a third embodiment.

  The mode for carrying out the present invention will be described in detail with reference to the following examples.

(Example 1)
The engine starting device of the first embodiment is applied to a vehicle that performs idling stop for automatically stopping the engine by cutting fuel injection to the engine when a predetermined engine stop condition is satisfied.
As shown in FIG. 1, this engine starting device has a starter body including a motor 2 and a pinion 3, and a pinion drive that drives the shift lever 4 to push the pinion 3 toward the ring gear 5 side (left side in the figure) of the engine E / G. A motor solenoid (hereinafter referred to as a solenoid SL1), a motor energizing solenoid (hereinafter referred to as a solenoid SL2) for opening and closing a main contact 6 provided in a motor circuit for energizing the motor 2 from the battery B, An auxiliary switch 8 having a built-in resistor 7 for suppressing the drive voltage and an idling stop ECU (hereinafter referred to as ECU 9) for controlling the operation of both solenoids SL1, SL2 and auxiliary switch 8 are provided.

The starter body is supplied with electric power from the battery B to generate a rotational force in the motor 2, and the rotational force is decelerated by a reduction device (not shown) and transmitted to the pinion 3. This starter body constitutes the starter 1 described in claim 1 together with the solenoid SL1 and the solenoid SL2.
The motor 2 includes a permanent magnet field that forms a magnetic field, an armature having a commutator on the axis of the armature shaft, a brush 10 that slides on the outer periphery of the commutator as the armature rotates. It is a known commutator motor. An electromagnet field can be employed instead of the permanent magnet field. The pinion 3 is disposed integrally with a clutch (not shown) on an output shaft 11 that is driven by the motor 2 and rotates, and the rotation of the output shaft 11 is transmitted through the clutch.
The clutch is arranged so as to be able to move integrally with the pinion 3 on the shaft of the output shaft 11 by helical spline fitting on the outer periphery of the output shaft 11.

Solenoid SL1 includes a coil (not shown) that is excited by battery B via drive relay 12, and plunger 13 that moves on the inner periphery of this coil. When the coil is excited and an electromagnet is formed, the plunger 13 is attracted by the electromagnet and moves along the inner circumference of the coil, thereby driving the shift lever 4 and pushing out the pinion 3 toward the ring gear 5.
The solenoid SL2 includes a coil 15 that is excited by the battery B via the drive relay 14 and a plunger (not shown) that moves on the inner periphery of the coil 15, and the main contact 6 is linked to the movement of the plunger. Open and close.
The drive relay 12 and the drive relay 14 are on / off controlled by a control command output from the ECU 9.

The resistor 7 is, for example, a nichrome wire, is disposed inside the auxiliary switch 8, and is connected to the motor circuit via two terminal bolts (not shown) provided on the auxiliary switch 8.
The auxiliary switch 8 has a current bypass function for short-circuiting both ends of the resistor 7, and a drive circuit 17 that switches ON / OFF of the current bypass function in accordance with excitation / non-excitation of the built-in coil 16. The current bypass function is formed by a bypass contact 18 that bypasses the resistor 7 and is connected to the motor circuit.
The bypass contact 18 is a so-called normally closed contact that opens when the auxiliary switch 8 is not operated (when the coil 16 is de-energized) and opens when the auxiliary switch 8 is operated (when the coil 16 is excited). is there. Therefore, the current bypass function is enabled (ON) when the auxiliary switch 8 is not operated, and is disabled (OFF) when the auxiliary switch 8 is operated.

Hereinafter, the control for opening the bypass contact 18 of the auxiliary switch 8 to disable the current bypass function by the ECU 9 is referred to as current bypass OFF, and the bypass contact 18 of the auxiliary switch 8 is closed to enable the current bypass function. This is called current bypass ON. That is, when the current bypass OFF is executed, the bypass contact 18 is opened, so that the driving voltage of the motor 2 is suppressed by the resistor 7. On the other hand, when the current bypass ON is executed, the bypass contact 18 is closed, so that the driving voltage of the motor 2 is not suppressed by the resistor 7 and the entire voltage of the battery B is applied to the motor 2.
The drive circuit 17 operates in response to the ON signal output from the drive relay 12 and controls the energization timing and energization time to the coil 16. That is, after the drive relay 12 is turned on, switching from current bypass ON to current bypass OFF to current bypass ON is controlled.

The ECU 9 is a control device according to the present invention. When an engine E / G restart request is generated after idling stop is performed, the ECU 9 restarts the engine E / G in response to the restart request. In addition, the operations of the solenoids SL1 and SL2 and the auxiliary switch 8 are controlled via the drive relay 12 and the drive relay 14. Hereinafter, the control for pushing the pinion 3 to the ring gear 5 side by the solenoid SL1 is referred to as pinion push-out control, and the control for starting energization to the motor 2 by closing the main contact 6 by the solenoid SL2 is motor energization control. Call it.
A control procedure of the ECU 9 related to the engine restart will be described based on a flowchart shown in FIG. In the flowchart shown in FIG. 2, a symbol “S” is attached to each step. That is, in the case of step 100, it is described as S100. In the step indicating determination, a symbol “Y” is attached when the determination result is YES, and a symbol “N” is attached when the determination result is NO.

First, in step 100, it is determined whether or not a restart request for the engine E / G has occurred. If it is determined that a restart request has been generated (determination result YES), it is determined in step 101 whether the peripheral speed difference between the ring gear 5 and the pinion 3 is large. Specifically, the peripheral speed difference between the ring gear 5 and the pinion 3 is compared with the first determination value. When the peripheral speed difference ≧ the first determination value (determination result YES), the motor energization control is controlled by the pinion extrusion control. Run earlier. On the other hand, when the peripheral speed difference <the first determination value (determination result NO), the pinion push-out control is executed prior to the motor energization control. That is, step 101 is the first determination means described in claims 1 and 3 of the present application, and determines whether or not the motor energization control is executed prior to the pinion extrusion control. Since the first determination value differs depending on the model of the engine E / G, a determination value set in advance for the engine E / G is used.

When the motor energization control is executed prior to the pinion extrusion control (when the determination result at step 101 is YES), it is determined at step 102 whether the motor is energized. When the motor is not energized (determination result NO) In step 103, motor energization control is executed.
Thereafter, the difference in the peripheral speed between the ring gear 5 and the pinion 3 is again compared with the first determination value in step 101, and if the determination result is NO (peripheral speed difference <first determination value), in step 104 It is determined whether or not the pinion has been pushed out. That is, it is determined whether or not pinion extrusion control is being executed. If the determination result is NO, it is determined in step 105 whether or not the pinion can be pushed out.

In step 105, for example, it can be determined whether or not the pinion can be pushed out by comparing the peripheral speed difference between the ring gear 5 and the pinion 3 with the second determination value. That is, it is determined that the pinion can be pushed out when the circumferential speed difference <the second determination value (determination result YES), and the pinion push-out is determined as not possible when the circumferential speed difference ≧ the second determination value (determination result NO). However, the second determination value is a smaller value than the first determination value used in step 101. Therefore, even if the peripheral speed difference <the first determination value in step 101, the pinion cannot be pushed out until the peripheral speed difference <the second determination value in step 105. This step 105 corresponds to the second determination means described in claim 3 of the present application.
When it is determined in step 105 that the pinion can be pushed out (determination result YES), the pinion extrusion control is executed in step 106, and then the current bypass OFF is executed in step 107.

  By executing the pinion extrusion control in step 106, if the determination result in the next step 104 is YES, it is determined in step 108 whether or not the pinion 3 is in contact with the ring gear 5. If the pinion 3 is in contact with the ring gear 5 (determination result YES), it is determined in step 109 whether the motor is energized. The process of step 109 is performed assuming that the process proceeds directly from step 101 to step 104 without shifting from step 101 to step 102. That is, if the determination result is NO in the first step 101, the process proceeds directly from step 101 to step 104. If the determination result in step 109 is NO, motor energization control is executed in step 110.

On the other hand, if the determination result in step 109 is YES, that is, if motor energization control has already been executed, current bypass ON is executed in step 111.
Next, in step 112, it is determined whether or not the engine start has been completed. This determination can be made based on, for example, whether or not the engine speed has reached the complete explosion speed. As with the previous determination value, the complete explosion speed of the engine E / G varies depending on the model. Therefore, the complete explosion speed of the engine E / G is measured in advance, and the data is stored in the ECU 9 for determination. To do.
If it is determined that the engine has been started (determination result YES), the motor energization control is terminated in step 113, and then the pinion extrusion control is terminated in step 114.

Next, the operation and effect of the first embodiment will be described with reference to the time chart shown in FIG.
In addition, the time chart of FIG. 3 has shown the example at the time of performing motor electricity supply control prior to pinion extrusion control. That is, the process proceeds from step 101 to step 102 in the flowchart of FIG.
When the idling stop is started at time t1 shown in FIG. 3, the fuel injection to the engine E / G is cut, and the engine E / G rotates by inertia. At this time, the engine rotational speed (= the rotational speed of the ring gear 5) gradually decreases while repeating the pulsating vertical movement as shown in the graph of FIG.

  If a restart request is generated at time t2 during inertial rotation of engine E / G, motor energization control is executed in response to the restart request. As a result, when the rotation speed of the pinion 3 increases and the peripheral speed difference between the pinion 3 and the ring gear 5 becomes small (peripheral speed difference <second determination value), the pinion extrusion control is executed at time t3, and the pinion 3 is pushed out to the ring gear 5 side. Current bypass OFF by the auxiliary switch 8 is executed at the same timing as this pinion push-out control. When the current bypass OFF is executed, the bypass contact 18 is opened, so that the driving voltage applied from the battery B to the motor 2 is suppressed by the resistor 7. As a result, the increase in the motor rotation speed is limited, so that the pinion 3 can be engaged with the ring gear 5 while maintaining the peripheral speed difference between the pinion 3 and the ring gear 5.

The current bypass OFF is executed for a predetermined time by the drive circuit 17 incorporated in the auxiliary switch 8. According to the flowchart of FIG. 2, current bypassing is performed from when a control command (command for turning on the drive relay 12) is output to the drive relay 12 of the solenoid SL <b> 1 until the pinion 3 contacts the ring gear 5. The OFF state is maintained.
Therefore, when the pinion 3 meshes with the ring gear 5, the current bypass is turned off and the current bypass is turned on, and the entire voltage of the battery B is applied to the motor 2, so that the rotational force necessary for cranking is transmitted from the pinion 3 to the ring gear 5. The When the start of the engine E / G is completed from the cranking, the idling stop control ends at time t4 shown in FIG.

As described above, when a restart request is generated during inertial rotation of the engine E / G, the motor 2 is energized to bring the rotational speed of the pinion 3 close to the rotational speed of the ring gear 5, thereby causing the ring gear during inertial rotation. 5 can be engaged with the pinion 3. In other words, there is no need to wait for the engine E / G to restart until the rotation of the engine E / G is completely stopped, so the time until the engine E / G is actually restarted after the restart request is generated. Can be shortened.
Further, by engaging the pinion 3 with the ring gear 5 in a state where the peripheral speed difference between the ring gear 5 and the pinion 3 is small (peripheral speed difference <second determination value), it is possible to reduce the sound and impact generated during the engagement. Therefore, wear of the ring gear 5 and the pinion 3 can be suppressed.

  Further, after the motor 2 is energized, when the rotational speed of the pinion 3 approaches the rotational speed of the ring gear 5, the current bypass OFF is executed to substantially maintain the peripheral speed difference between the ring gear 5 and the pinion 3. 3 can be meshed with the ring gear 5. In this method, the motor energization control only needs to be performed once while the idling stop control is being performed (between times t1 and t4 in FIG. 3). That is, in Patent Document 1, which is the prior art, the drive motor switch is turned on and off twice, so it is necessary to take an interval after the pinion 3 is engaged with the ring gear 5 and before the drive motor switch is turned on again. . On the other hand, in the engine starting device of the first embodiment, it is not necessary to take an interval, so that the engine can be started more quickly. Further, compared with Patent Document 1, since it is only necessary to energize the motor 2 only once, it is possible to suppress the wear of the brush 10 due to the inrush current flowing through the motor 2, and to extend the life of the brush 10. is there.

Furthermore, since the inrush current that flows when the motor 2 is started up can be suppressed by executing the current bypass OFF to suppress the drive voltage of the motor 2, welding of the main contact 6 that interrupts the energization current of the motor 2 can be prevented.
Further, in the engine starting device of the first embodiment, when the drive relay 12 of the solenoid SL1 is turned on, the drive circuit 17 of the auxiliary switch 8 is activated in response to the on signal output from the drive relay 12, and the drive circuit 17 Can switch ON / OFF of the current bypass function. According to this configuration, since the drive relay 12 can be shared by the solenoid SL1 and the auxiliary switch 8, it is not necessary to provide a dedicated drive relay for the auxiliary switch 8. Thereby, the cost can be reduced by reducing the number of parts.

Examples 2 and 3 according to the present invention will be described below.
(Example 2)
In the second embodiment, after the pinion push-out control is performed, the switching timing from the current bypass OFF to the current bypass ON is different from the first embodiment.
Hereinafter, the control procedure of the ECU 9 will be described with reference to the flowchart shown in FIG. Note that the processing from steps 200 to 210 in the second embodiment is the same as the processing from steps 100 to 110 in the first embodiment, and the first embodiment is referred to for the description.

If the determination result in step 209 is YES, that is, if motor energization control has already been executed, it is determined in step 211 whether or not the engagement between the pinion 3 and the ring gear 5 has been completed. For this determination, for example, in the engine E / G, after the pinion extrusion control is started in step 206, the time until the engagement between the pinion 3 and the ring gear 5 is completed is measured in advance, and the data is used as the basis. Can be determined.
When the meshing between the pinion 3 and the ring gear 5 is completed (determination result YES), current bypass ON is executed in step 212. Thereafter, steps 213 to 215 are the same as steps 112 to 114 of the first embodiment.

  As described above, in Example 2, the current bypass OFF is continued until the engagement between the pinion 3 and the ring gear 5 is completed after the pinion extrusion control is started. In this case, since the drive voltage of the motor 2 is suppressed until the pinion 3 meshes with the ring gear 5, the impact when the pinion 3 jumps into the ring gear 5 after contacting the ring gear 5 can be further reduced. In other words, the engagement between the pinion 3 and the ring gear 5 can be performed more smoothly, wear of the ring gear 5 and the pinion 3 can be suppressed, and noise generated during the engagement can also be reduced.

(Example 3)
The third embodiment is an example in which the current bypass is turned off in response to the pulsation of the engine speed that occurs during inertial rotation of the engine E / G.
As shown in FIG. 5, the engine starter according to the third embodiment includes a drive relay 19 for turning on / off the operation of the auxiliary switch 8, in other words, for intermittently supplying a current to the coil 16. The auxiliary switch 8 of the first embodiment described above incorporates a drive circuit 17 that is activated upon receiving an ON signal output from the drive relay 12 of the solenoid SL1, and this drive circuit 17 controls the execution time of the current bypass OFF. doing. On the other hand, in Example 3, since the current bypass OFF may be executed a plurality of times, the ON / OFF operation of the drive relay 19 is controlled by the ECU 9 to switch the current bypass function ON / OFF.

Hereinafter, the control procedure of the ECU 9 according to the third embodiment will be described with reference to the flowchart shown in FIG. Steps 300 to 304 are the same as steps 100 to 104 in the first embodiment and steps 200 to 204 in the second embodiment.
If the determination result in step 304 is NO, it is determined in step 305 whether or not the engine speed is decreasing. It should be noted that the engine E / G whose fuel supply has been stopped due to idling stop causes pulsation in the rotational speed even during inertial rotation, as shown in the graph representing the engine rotational speed in FIG. That is, the engine speed gradually decreases while repeating pulsating up and down movements. The meaning of “decreasing engine speed” in step 305 refers to a region where the engine is descending due to pulsating vertical movement.
If it is determined in step 305 that the engine speed is decreasing (determination result YES), current bypass OFF is executed in step 306. On the other hand, if it is determined that the engine speed is not decreasing (determination result NO), current bypass ON is executed in step 307.

Thereafter, in step 308, it is determined whether or not the pinion can be pushed out. While the determination result in step 308 is NO, current bypass OFF is executed in step 306 or current bypass ON is executed in step 307 according to the determination result in step 305.
When it is determined in step 308 that the pinion can be pushed out (determination result YES), the pinion extrusion control is executed in step 309, and then the current bypass OFF is executed in step 310. Thereafter, steps 311 to 318 are the same as the processing of steps 208 to 215 of the second embodiment. In step 314, as in the second embodiment, it is determined whether or not the meshing between the pinion 3 and the ring gear 5 has been completed. However, step 314 is omitted, and the same control procedure as in the first embodiment is performed. It can also be executed.

Next, operations and effects of the third embodiment will be described with reference to a time chart shown in FIG.
In addition, the time chart of FIG. 7 has shown the example at the time of performing motor electricity supply control prior to pinion extrusion control similarly to Example 1. FIG.
After the idling stop is started at time t1 shown in FIG. 7, when a restart request is generated at time t2 during inertial rotation of the engine E / G, motor energization control is executed in response to the restart request. Thereafter, at time t3 when the engine speed is decreasing, current bypass OFF is executed for a predetermined time. After the current bypass is turned ON, at time t4 when the engine speed is decreasing, again at the same timing as the pinion push-out control. The current bypass is turned off.

When the pinion 3 is engaged with the ring gear 5 in the state where the current bypass is OFF, the current bypass is turned off and the current bypass is turned ON, and the entire voltage of the battery B is applied to the motor 2, so that the rotational force necessary for cranking is It is transmitted from the pinion 3 to the ring gear 5. When engine E / G is completely detonated from cranking and engine start is completed, the idling stop control is terminated at time t5.
As described above, it is possible to make the rotation speed of the pinion 3 follow the rotation speed of the ring gear 5 by executing the current bypass OFF in accordance with the decrease in the engine rotation speed due to the pulsation. As a result, it becomes easy to synchronize the rotation speed of the pinion 3 when the rotation speed of the ring gear 5 decreases, so that the engagement between the pinion 3 and the ring gear 5 can be performed more smoothly.

(Modification)
In the first embodiment, the drive relay 12 is shared by the solenoid SL1 and the auxiliary switch 8, in other words, the drive circuit 17 of the auxiliary switch 8 is activated by using the output of the drive relay 12 of the solenoid SL1 as a trigger. In this case, the pinion push-out control and the current bypass OFF can be executed at the same timing, but the current bypass OFF can be executed with a certain delay time with respect to the start timing of the pinion push-out control.

1 Starter 2 Motor 3 Pinion 5 Ring Gear 6 Main Contact 7 Resistor 8 Auxiliary Switch 9 ECU (Control Device)
17 Drive circuit 18 Bypass contact E / G Engine SL1 Pinion drive solenoid SL2 Motor energization solenoid

Claims (8)

The present invention is applied to a vehicle that performs idling stop for automatically stopping the engine (E / G) when a predetermined engine stop condition is satisfied, and the engine (E / G) is restarted when the engine (E / G) is requested to restart. E / G) an engine starter for restarting,
The pinion (3) is meshed with the ring gear (5) of the engine (E / G), and the rotational force generated in the motor (2) is transmitted from the pinion (3) to the ring gear (5) to transmit the engine (E / G) starter (1),
A resistor (7) provided in a motor circuit for energizing the motor (2) from the battery (B) to suppress the drive voltage of the motor (2);
An auxiliary switch (8) having a current bypass function for short-circuiting both ends of the resistor (7), and for turning on and off the current bypass function in accordance with excitation / non-excitation of the built-in coil (16);
A control device (9) for controlling the operation of the starter (1) and the auxiliary switch (8),
The starter (1)
An electromagnet is formed by energization, and a pinion drive solenoid (SL1) that pushes the pinion (3) toward the ring gear (5) using the attraction force of the electromagnet;
An electromagnet is formed by energization, and a motor energization solenoid (SL2) that opens and closes a main contact (6) provided in the motor circuit by on / off control of the electromagnet;
When the control for turning off the current bypass function by energizing the coil (16) of the auxiliary switch (8) is called current bypass OFF,
The control device (9) is configured to drive the pinion when a restart request of the engine (E / G) occurs during inertial rotation until the rotation of the engine (E / G) is stopped by the idling stop. The operation of the solenoid (SL1) and the operation of the motor energization solenoid (SL2) are individually controlled, and at least before the pinion (3) contacts the ring gear (5), the current bypass OFF is executed. The drive voltage of the motor (2) is suppressed ,
Further, the control for energizing the pinion drive solenoid (SL1) to push out the pinion (3) to the ring gear (5) side is called pinion extrusion control,
When energizing the motor energizing solenoid (SL2) and closing the main contact (6) to start energizing the motor (2) is called motor energization control.
The control device (9) compares a peripheral speed difference between the ring gear (5) and the pinion (3) with a first determination value in response to a restart request of the engine (E / G). 1 determination means,
When the determination result of the first determination means is the peripheral speed difference ≧ the first determination value, the motor energization control is executed before the pinion push-out control and the current bypass OFF,
When the determination result of the first determination means is the peripheral speed difference <the first determination value, the pinion push-out control and the current bypass OFF are executed before the motor energization control. Starter. The engine starter according to claim 1,
The control device (9) performs the current bypass OFF while the engine speed is decreasing with respect to the vertical movement of the engine speed that occurs during inertial rotation of the engine (E / G). Engine starter. The engine starter according to claim 1 ,
The control device (9) determines the difference between the peripheral speeds of the ring gear (5) and the pinion (3) after the determination result of the first determination means becomes the peripheral speed difference <the first determination value. A second determination means for comparing the second determination value with a second determination value that is smaller than the first determination value,
Before the determination result of the second determination means becomes the difference between the peripheral speeds <the second determination value, the engine speed against the pulsation of the engine speed generated during inertial rotation of the engine (E / G). An engine starter characterized in that the current bypass OFF is executed during a descent of the number. The present invention is applied to a vehicle that performs idling stop for automatically stopping the engine (E / G) when a predetermined engine stop condition is satisfied, and the engine (E / G) is restarted when the engine (E / G) is requested to restart. E / G) an engine starter for restarting,
The pinion (3) is meshed with the ring gear (5) of the engine (E / G), and the rotational force generated in the motor (2) is transmitted from the pinion (3) to the ring gear (5) to transmit the engine (E / G) starter (1),
A resistor (7) provided in a motor circuit for energizing the motor (2) from the battery (B) to suppress the drive voltage of the motor (2);
An auxiliary switch (8) having a current bypass function for short-circuiting both ends of the resistor (7), and for turning on and off the current bypass function in accordance with excitation / non-excitation of the built-in coil (16);
A control device (9) for controlling the operation of the starter (1) and the auxiliary switch (8),
The starter (1)
An electromagnet is formed by energization, and a pinion drive solenoid (SL1) that pushes the pinion (3) toward the ring gear (5) using the attraction force of the electromagnet;
An electromagnet is formed by energization, and a motor energization solenoid (SL2) that opens and closes a main contact (6) provided in the motor circuit by on / off control of the electromagnet;
When the control for turning off the current bypass function by energizing the coil (16) of the auxiliary switch (8) is called current bypass OFF,
The control device (9) is configured to drive the pinion when a restart request of the engine (E / G) occurs during inertial rotation until the rotation of the engine (E / G) is stopped by the idling stop. The operation of the solenoid (SL1) and the operation of the motor energization solenoid (SL2) are individually controlled, and at least before the pinion (3) contacts the ring gear (5), the current bypass OFF is executed. The drive voltage of the motor (2) is suppressed,
Furthermore, it has a drive relay (12) that is on / off controlled by a control command output from the control device (9). The drive relay (12) is connected to the pinion drive solenoid (SL1) and the auxiliary switch (8). Engine starter characterized in that it is shared with. The engine starting device according to claim 1 or 2 ,
The drive relay (12) is controlled to be turned on and off by a control command output from the control device (9). The drive relay (12) is composed of the pinion drive solenoid (SL1) and the auxiliary switch (8). An engine starter that is shared. The engine starter according to any one of claims 1 , 2, 4 , and 5,
The engine starter characterized in that the auxiliary switch (8) has a drive circuit (17) for switching the current bypass function on and off. The engine starting device according to any one of claims 1, 2 , 4 to 6,
The control device (9) outputs the current bypass OFF until the pinion (3) comes into contact with the ring gear (5) after outputting a control command for energizing the pinion drive solenoid (SL1). The engine starting device is characterized by continuously executing. The engine starting device according to any one of claims 1, 2 , 4 to 6,
The control device (9) sets the current bypass OFF until the pinion (3) meshes with the ring gear (5) after outputting a control command for energizing the pinion drive solenoid (SL1). An engine starting device that is continuously executed.

Images