JP2018091340A - Engine starting device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an engine starting device capable of shortening an engine starting time without enlarging an electromagnetic solenoid device 10.SOLUTION: Starter characteristic switching means can switch at least two stages between high rotation type and low rotation type. By using two plungers, a shift lever can be operated at one side, and motor rotational force can be transmitted to a pinion at the other side. A moving direction of two plungers is in parallel with a direction to push out the pinion, and electric power is supplied to a motor by movement of the second plunger for transmitting rotational force of the motor from the pinion to a ring gear, after the pinion is brought into contact with the ring gear, thus rotational force of low rotation is generated, and the pinon and the ring gear are engaged. Low rotation type starter characteristic is applied from start of energization to a solenoid SL1 to completion of engagement of the pinion 9 and the ring gear 8, and cranking to switch to high rotation-type starter characteristic is performed on the basis of the engagement.SELECTED DRAWING: Figure 1

Description

The present invention relates to an engine starter capable of switching an output characteristic of a starter between a high rotation type and a low rotation type.

Conventionally, an idling stop starter has been requested to shorten the engine restart time as much as possible in order to improve the feeling of the driver and passengers when the engine is restarted. In order to shorten the restart time, there is a method of increasing the cranking rotational speed. However, in order to achieve both startability at low temperatures with high engine friction, it is necessary to use a motor with a large size and high output.
As a method of increasing the cranking rotation speed at the restart without increasing the motor size, there is a method of switching the output characteristics of the high rotation type and the low rotation type as necessary.
For example, in Patent Document 1, a motor field coil is provided with a series-wound coil and a shunt coil, and a field current supplied to the shunt coil is controlled by an ECU so that a high-rotation type characteristic and a high-power- A technique for switching between torque type characteristics is disclosed.

JP 2004-197719 A

In the above prior art (Patent Document 1), for example, the engine start time from the idling stop can be shortened by setting the output characteristics at the time of engine start to a high rotation type. However, in the high rotation type characteristics, the pinion rotation speed becomes too high when the motor is engaged, so that the pinion becomes difficult to engage with the ring gear, and there is a problem that the engagement reliability is lowered. As a method for solving this problem, it is conceivable to increase the load of the drive spring that pushes out the pinion during meshing.
However, when the load of the drive spring is increased, it is necessary to increase the suction force of the solenoid that sucks the plunger against the reaction force of the drive spring. As a result, a problem arises that the solenoid becomes larger and the mountability on the vehicle deteriorates, and the starter cost increases.
The present invention has been made to solve the above-described problems, and an object of the present invention is to provide an engine starter that can shorten the engine start time without increasing the size of the solenoid.

The present invention pushes the pinion (9) toward the ring gear (8) of the engine by operating the shift lever (22) using the suction force of the solenoid (SL1) to the first plunger (21), and
A gear jump that starts the engine by transmitting the rotational force of the motor (5) from the pinion (9) to the ring gear (8) according to the movement of the second plunger (23) by the suction force of the solenoid (SL2). Formula starter (1),
An engine starter comprising starter characteristic switching means capable of switching an output characteristic (hereinafter referred to as starter characteristic) of the starter (1) between a high rotation type and a low rotation type in at least two stages,
The moving direction of the first plunger (21) by the solenoid (SL1) and the moving direction of the second plunger (23) are on the same axis and parallel to the direction in which the pinion is pushed out,
When performing cranking with the high-rotation type starter characteristics, after the starter (1) starts to operate, the pinion (9) is pushed out by the suction force of the solenoid (SL1) to the first plunger (21). Then, the second plunger (23) is moved by the suction force of the solenoid (SL2), and thereby the electric power is supplied to the motor (5) to reduce the rotational force of the low rotation. Is generated, and the rotational force is transmitted to the pinion (9) to establish engagement between the pinion (9) and the ring gear (8), and at least engagement between the pinion (9) and the ring gear (8). The starter characteristics switching means is based on the engagement established by the low rotational torque, and the high rotational starter characteristics And switches the motor characteristics.

  The starter of the present invention is set to a low rotation type until cranking is completed at least until the meshing between the pinion and the ring gear is completed when cranking with a high rotation type starter characteristic. Compared with the case of meshing with the motor, the number of pinion rotations when the motor is meshed can be reduced. In other words, after the pinion pushed out by the operation of the solenoid comes into contact with the ring gear, the rotation of the pinion is rotated by the rotation of the motor and the pinion rotation speed is reduced, so that the meshing reliability is improved.

Further, since it is not necessary to increase the load of the drive spring in order to push the pinion into the ring gear, it is possible to avoid an increase in the size of the solenoid. That is, the engine start time can be shortened without increasing the size of the solenoid.
Further, since cranking is performed by switching to the high rotation type based on the meshing between the pinion and the ring gear, the time from the start of the starter operation to the engine start can be shortened. In particular, when the present invention is applied to an idling stop starter, the engine start time from the idling stop can be shortened, which contributes to an improved feeling for the driver and passengers.
Further, after the pinion and the ring gear are brought into contact with each other, electric power is supplied to the motor by the movement of the second plunger that is lighter than that of the dual-purpose plunger, and a rotational force is generated. Therefore, the vibration due to the movement of the second plunger is small, and the vibration of the pinion is suppressed to be small during the rotation of the pinion, and the meshing phase is easily matched. Therefore, coupled with the low rotational torque, it is possible to stably ensure the engagement timing of the meshing phase between the pinion and the ring gear for a long time, and the probability of meshing is improved even if there is little rotation performance from the start of rotation. The pinion end surface and the ring gear end surface can be engaged with each other while reducing end surface wear when rotating while abutting.

1 is an overall configuration diagram of an engine starter according to Embodiment 1. FIG. It is a wave form diagram which shows the starter electric current at the time of engine starting, and the fluctuation | variation of an engine speed. FIG. 3 is an enlarged view of the waveform diagram shown in FIG. 2.

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

[Example 1]
As shown in FIG. 1, the engine starter according to the first embodiment includes a gear dive starter 1, a control device (hereinafter referred to as an ECU 4) that controls the operation of the starter 1 through starter relays 2 and 3, a starter Starter characteristic switching means (to be described later) capable of switching one output characteristic (hereinafter referred to as starter characteristic).
The starter 1 includes a motor 5 that generates a rotational force, an output shaft 7 to which the rotational force of the motor 5 is transmitted via a variable speed reduction mechanism 6 (described later), and a driving torque of the motor 5 that is transmitted to an engine ring gear 8. It consists of a pinion 9 for transmitting to the electromagnetic wave and an electromagnetic solenoid device 10 which will be described later.
The motor 5 includes a field element configured by arranging a permanent magnet 12 on the inner periphery of a yoke 11, an armature 14 having a commutator 13 on an axis, and a commutator 13 as the armature 14 rotates. DC brushed motor having a brush 15 and the like that slide on the outer periphery of the brush. The field element may be a wound field type that uses a field winding instead of the permanent magnet 12.

The output shaft 7 is disposed coaxially with the armature shaft 14 a of the motor 5 via the variable speed reduction mechanism 6, and the tip on the side opposite to the motor is supported by the starter housing 17 via the bearing 16.
The pinion 9 is directly splined to the outer periphery of the inner tube 18a provided in the clutch 18, and is urged by the pinion spring 19 in the distal direction (left direction in the drawing) of the inner tube 18a, and is attached to the distal end portion of the inner tube 18a. The pinion stopper 20 is in contact.
The clutch 18 is helically splined to the outer periphery of the output shaft 7 to transmit the motor torque to the pinion 9, while the rotation of the pinion 9 is transmitted to the output shaft 7 when the pinion 9 is rotated by the engine. It constitutes a one-way clutch to prevent.

The electromagnetic solenoid device 10 includes a solenoid SL1 that pushes the pinion 9 together with the clutch 18 through the shift lever 22 as the plunger 21 moves, and a solenoid SL2 that opens and closes the main contact according to the movement of the plunger 23.
The main contact is a set of fixed contacts connected to the energization path for supplying power from the battery 24 to the motor 5 via the two terminal bolts 25 and 26, and a set according to the movement of the plunger 23. And a movable contact that electrically opens and closes between the fixed contacts.
The two terminal bolts 25 and 26 are fixed to a resin cover 27 that covers the rear end side (the right side in FIG. 1) of the electromagnetic solenoid device 10. One terminal bolt 25 is connected to the positive terminal of the battery 24 via the battery cable 28, and the other terminal bolt 26 is connected to the positive brush 15 via the motor lead wire 29.

Subsequently, the starter characteristic switching means of the present invention will be described.
The starter characteristic switching means includes the variable deceleration mechanism unit 6 and a deceleration operation switching unit 30 that can switch the variable deceleration mechanism unit 6 between a deceleration mode and a non-deceleration mode.
The variable reduction mechanism unit 6 is configured using, for example, a known planetary gear reduction device.
The deceleration operation switching unit 30 can be switched between a deceleration mode for restricting rotation of an internal gear (not shown) of the planetary gear reduction device and a non-deceleration mode for releasing rotation restriction of the internal gear. The deceleration operation switching unit 30 includes, for example, an electric actuator (not shown), and switches the variable deceleration mechanism unit 6 to a deceleration mode or a non-deceleration mode in conjunction with the operation of the electric actuator.

In the deceleration mode, the rotation of the internal gear is restricted, so that the variable reduction mechanism 6 functions as a normal reduction device. That is, the rotation of the motor 5 is decelerated by the variable deceleration mechanism 6 and transmitted to the output shaft 7.
In the non-deceleration mode, the rotation restriction of the internal gear is released and the rotation becomes possible, so that the variable deceleration mechanism 6 does not function as a reduction gear. In other words, when the motor 5 rotates, the gears (internal gear, planetary gear, sun gear) of the variable reduction mechanism unit 6 rotate as a unit, so that the rotation of the motor 5 is decelerated by the variable reduction mechanism unit 6. Without being transmitted to the output shaft 7. That is, the starter characteristic becomes a high torque low rotation type by setting the variable speed reduction mechanism unit 6 to the deceleration mode, and becomes a low torque high rotation type by setting the non-deceleration mode.

Next, the operation of the starter 1 will be described.
Here, a case where cranking is performed with a starter characteristic of a low torque and high rotation type when the engine is restarted from an idling stop will be described.
When an engine restart request is generated, the ECU 4 first turns on the starter relay 2 and then turns on the starter relay 3, for example.
When the starter relay 2 is turned on and the solenoid SL1 is activated, the pinion 9 is pushed together with the clutch 18 through the shift lever 22 in the counter-motor direction (left direction in FIG. 1). At this time, if the meshing phase between the pinion 9 and the ring gear 8 is shifted, the teeth of the pinion 9 and the end surfaces of the teeth of the ring gear 8 come into contact with each other.

  Thereafter, when the starter relay 3 is turned on and the solenoid SL2 is actuated, the main contact is closed and electric power is supplied from the battery 24 to the motor 5 to generate a rotational force in the motor 5. The rotational speed of the motor 5 is decelerated by the variable reduction mechanism 6 and transmitted to the output shaft 7, and further transmitted from the output shaft 7 to the pinion 9 via the clutch 18. As a result, when the pinion 9 rotates and the meshing phase with the ring gear 8 matches, the teeth of the pinion 9 jump between the teeth of the ring gear 8 and the meshing between the pinion 9 and the ring gear 8 is established. As a result, the motor torque is transmitted from the pinion 9 to the ring gear 8 to crank the engine.

Here, after the starter 1 starts operating, the variable speed reduction mechanism unit 6 is set to the deceleration mode at least until the engagement between the pinion 9 and the ring gear 8 is completed, and after the engagement between the pinion 9 and the ring gear 8 is completed, Switch to non-deceleration mode. That is, as shown in FIG. 2, the starter characteristic is a high-torque low-rotation type from the start of energization to the solenoid SL1 until the engagement between the pinion 9 and the ring gear 8 is completed (t1 in the figure). At the time of cranking, it becomes a low torque high rotation type.
The timing for switching the starter characteristic from the high torque low rotation type to the low torque high rotation type can be set by, for example, the timer circuit 31 (see FIG. 1). Specifically, a time interval from the start of energization to the solenoid SL1 to the completion of the engagement between the pinion 9 and the ring gear 8 is measured in advance, and the measurement time is set in the timer circuit 31. As shown in FIG. 1, the timer circuit 31 starts to operate in response to an ON signal of the starter relay 2, and when the set time t <b> 1 (see FIGS. 2 and 3) has been counted, Energize the actuator.

[Operation and Effect of Example 1]
When the engine is restarted from idling stop, it is a high torque low rotation starter characteristic at least from the start of energization to the solenoid SL1 until the pinion 9 jumps into the ring gear 8 and the engagement is completed, and the pinion rotational speed is the lowest Become. For this reason, as compared with a low torque high rotation type starter, as shown in FIG. 3, the inclination of increasing the pinion rotational speed from the start of energization to the solenoid SL2 until the completion of the engagement between the pinion 9 and the ring gear 8 is reduced. Yes. That is, the pinion rotation speed when the motor is engaged is reduced as compared with a low torque high rotation starter. The waveform diagram of FIG. 3 is an enlarged view between OT shown on the time axis (horizontal axis) of FIG. Further, the pinion rotation speed at the time of the engagement of the motor means that the pinion 9 is rotated by the rotation of the motor 5 after the pinion 9 abuts on the ring gear 8 and the meshing phase with the ring gear 8 coincides with the ring gear 8. The rotation speed of the pinion 9 when it jumps into and meshes.

As described above, in the engine starting device of the first embodiment, the meshing reliability is improved by reducing the pinion rotation speed when the motor is meshed. Thus, it is not necessary to increase the load of the drive spring 32 (see FIG. 1) that pushes out the pinion 9 when the motor is engaged, and therefore it is not necessary to increase the suction force of the solenoid SL1. As a result, the electromagnetic solenoid device 10 does not increase in size, and it is possible to avoid a deterioration in mountability on the vehicle.
Further, after the meshing between the pinion 9 and the ring gear 8 is completed, the cranking is performed by switching to the low torque high rotation type, so that the cranking rotational speed can be increased and the engine start time can be shortened. In particular, in vehicles equipped with an idling stop system, it is possible to shorten the time from the start of starter 1 operation (the start of energization to solenoid SL1 in the first embodiment) to the restart of the engine, which contributes to an improved feeling for drivers and passengers. To do.

Further, since the timer circuit 31 is used to switch the state of the variable deceleration mechanism 6 (deceleration mode and non-deceleration mode), it is easy to switch the starter characteristic from the high torque low rotation type to the low torque high rotation type. And it can be controlled appropriately.
In addition, since the starter 1 of the first embodiment uses the brushed DC motor 5, for example, compared with a case where an AC motor that requires an inverter for controlling a large current is used, this cost is low. The engine starting device of the invention can be realized.

Hereinafter, other embodiments according to the present invention will be described.
In addition, what shows the component and structure which are common in Example 1 is given the same code | symbol as Example 1, and abbreviate | omits detailed description.
[Example 2]
The starter 1 described in the first embodiment is provided with the variable reduction mechanism 6 for switching the output characteristics, but a plurality of variable reduction mechanisms 6 can be combined in series. In other words, in the second embodiment, the state (deceleration mode and non-deceleration mode) of each variable deceleration mechanism unit 6 combined in series is individually switched by the deceleration operation switching unit 30 so that the starter characteristics are at least in three stages or more. Can be switched.

When the configuration of the second embodiment is adopted, the output characteristics when the motor is engaged may be set to a characteristic on the lower torque side than the characteristic that provides the highest torque (however, the torque characteristics higher than the output characteristics used for cranking). it can.
In the case of the high torque low rotation type, as described in the first embodiment, the pinion rotation speed at the time of motor engagement can be reduced, so that the engagement reliability is improved. However, if the starting torque of the motor 5 is too high, the end surface wear between the pinion 9 and the ring gear 8 that occurs when the motor is engaged increases, and a problem arises that durability performance that can maintain the engagement performance decreases. On the other hand, until the meshing between the pinion 9 and the ring gear 8 is completed, it is possible to select a lower torque characteristic, that is, an appropriate torque characteristic than that in the case of the highest torque and low rotation type. As a result, it is possible to improve the meshing performance by reducing the number of rotations of the pinion at the time of meshing the motor while maintaining the durability performance while minimizing the increase in end face wear.

[Modification]
In the first embodiment, the timer circuit 31 is used to switch the state of the variable deceleration mechanism unit 6, but instead of providing the timer circuit 31, the ECU 4 can have the function of the timer circuit 31. The timer circuit 31 according to the first embodiment counts the time t1 from the start of energization of the solenoid SL1 until the starter characteristic is switched. In other words, the timer circuit 31 starts the counting operation based on the ON signal of the starter relay 2. The counting operation may be started based on an ON signal of the starter relay 3 that starts energization of the solenoid SL2. That is, the electric actuator of the deceleration operation switching unit 30 may be energized when the time t2 (see FIGS. 2 and 3) from the start of energization of the solenoid SL2 is counted.

The starter characteristic switching means of the present invention has at least three or more stages between the high torque low rotation type and the low torque high rotation type in the case of Example 1 where the starter characteristic is switched from the high torque low rotation type to the low torque high rotation type. Although the example of the embodiment 2 for switching to is described, the starter characteristics may be switched (variable) steplessly instead of stepwise.
The electromagnetic solenoid device 10 described in the first embodiment is a so-called tandem solenoid type having a solenoid SL1 for pushing out the pinion 9 and a solenoid SL2 for opening and closing the main contact. It is also possible to use an electromagnetic switch that opens and closes with a single solenoid.

1 Gear dive starter 5 Motor 6 Variable speed reduction mechanism (starter characteristics switching means)
8 Ring gear 9 Pinion 30 Deceleration operation switching part (Starter characteristic switching means)
31 Timer circuit (Timer function)
SL1 solenoid

Claims (5)

The pinion (9) is pushed toward the ring gear (8) of the engine by the operation of the shift lever (22) using the suction force of the solenoid (SL1) to the first plunger (21), and
A gear jump that starts the engine by transmitting the rotational force of the motor (5) from the pinion (9) to the ring gear (8) according to the movement of the second plunger (23) by the suction force of the solenoid (SL2). Formula starter (1),
An engine starter comprising starter characteristic switching means capable of switching an output characteristic (hereinafter referred to as starter characteristic) of the starter (1) between a high rotation type and a low rotation type in at least two stages,
The moving direction of the first plunger (21) by the solenoid (SL1) and the moving direction of the second plunger (23) are on the same axis and parallel to the direction in which the pinion is pushed out,
When performing cranking with the high-rotation type starter characteristics, after the starter (1) starts to operate, the pinion (9) is pushed out by the suction force of the solenoid (SL1) to the first plunger (21). Then, the second plunger (23) is moved by the suction force of the solenoid (SL2), and thereby the electric power is supplied to the motor (5) to reduce the rotational force of the low rotation. Is generated, the rotational force is transmitted to the pinion (9), the meshing of the pinion (9) and the ring gear (8) is established,
At least until the meshing between the pinion (9) and the ring gear (8) is completed, the low-rotation type starter characteristic is provided, and the starter characteristic switching means is based on the meshing established by the low rotational torque. An engine starter characterized by switching to a high rotation type starter characteristic.
Using the suction force of the solenoid (SL1), the pinion (9) is jumped into the ring gear (8) of the engine, and the rotational force of the motor (5) is transmitted from the pinion (9) to the ring gear (8). A gear dive starter (1) for starting the engine,
A starter characteristic switching means (6, 6) capable of switching the output characteristic (hereinafter referred to as starter characteristic) of the starter (1) between the low torque high rotation type and the high torque low rotation type in at least two stages or continuously. 30) an engine starting device comprising:
When cranking is performed with the starter characteristic of the low torque and high rotation type, after the starter (1) starts operating, the high torque is at least until the engagement between the pinion (9) and the ring gear (8) is completed. An engine starter characterized by low starter characteristics. In the engine starting device according to any one of claims 1 to 3,
The starter (1) is configured so that the timing at which the starter characteristic is switched from the low rotation type to the high rotation type (referred to as switching timing) is after completion of meshing of the pinion (9) and the ring gear (8). An engine starter characterized in that the time from the start of operation to the switching timing is set or controlled by a timer function (31). 2. The engine starter according to claim 1, wherein the low-rotation type starter characteristic is such that a meshing phase between the pinion and the ring gear coincides with the start of energization of a solenoid (SL2) that attracts the second plunger (23). An engine starter characterized in that the pinion speed continues to rise until The engine starter according to any one of claims 1 to 3, wherein the low-rotation type starter characteristic has a smaller inclination of increasing the pinion rotational speed than the high-rotation type starter characteristic. Engine starter. 5. The engine starter according to claim 1, wherein the motor is a DC motor with a brush.

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