JP4131361B2 - Automatic engine starter - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention belongs to the technical field of a starting device for starting an engine of an automobile or the like. The present invention is suitable for vehicles that require frequent engine restarts, such as hybrid cars and automobiles that have a device that automatically stops the engine when the vehicle stops, such as waiting for a signal.
[0002]
[Prior art]
An automatic engine is usually equipped with an overrunning clutch so that the starter motor does not rotate after the engine is started. Regarding the overrunning clutch, for example, a technique disclosed in Japanese Patent Application Laid-Open No. 9-172735 (Japanese Patent Application No. 8-200295) is known.
[0003]
If the engine starter is equipped with an overrunning clutch, the driven shaft of the clutch that is directly connected to the engine crankshaft or indirectly via a gear, belt / pulley, etc. Rotating at a higher speed than the drive shaft driven by the starter motor. Then, the driving force from the starter motor is no longer transmitted to the driven shaft on the engine side via the overrunning clutch. Therefore, stopping the energization of the starter motor as soon as possible once the engine is running will prolong the life of the starter motor and reduction gear built in the starter, prevent vibration and noise, and reduce the power. It is important to save.
[0004]
Thus, as a conventional technique, a technique for quickly stopping energization of the starter motor when the engine is started can be considered. As such a technique, there is one that measures the power generation voltage of the alternator and the power supply voltage of the battery, and controls energization to the starter motor.
[0005]
[Problems to be solved by the invention]
However, in the above-described conventional technology, the influence of the state of the engine, the alternator, and the battery is large in the determination of engine start. Therefore, in order to confirm that the engine has started reliably, it is necessary to continue energizing the starter motor with a certain margin. Therefore, according to this conventional technique, there is an inconvenience that energization of the starter motor cannot be stopped sufficiently early if an attempt is made to start the engine more reliably. As a result, it cannot be said that the effects of prolonging the life of the starter motor and the speed reducer built in the starter, preventing the vibration and noise, and saving electric power are sufficiently obtained.
[0006]
Accordingly, the present invention provides a problem to be solved by providing an engine automatic starter capable of extending the life of a starter motor by stopping energization to the starter motor at an early stage while almost certainly starting the engine. To do.
[0007]
[Means for Solving the Problems]
In order to solve the above problems, the inventors have invented the following means.
[0008]
(First means)
The first means of the present invention is the automatic engine starter according to claim 1. That is, the feature of this means is that the control device detects a rotational speed of the driving shaft and a driven rotational speed that is the rotational speed of the driven shaft, and the driving rotational speed. A rotation speed comparison means for comparing the rotation speed with the driven rotation speed, and an energization stop determination means for stopping energization of the starter motor when a predetermined condition is satisfied based on a comparison result of the rotation speed comparison means. It is.
[0009]
In this means, the control device has a rotation speed detection means, a rotation speed comparison means, and an energization stop determination means.
[0010]
First, the rotational speed detection means detects the drive rotational speed and the driven rotational speed, and aligns both data for the rotational speed comparison means. Here, the drive rotation speed and the driven rotation speed may be equivalent to those detected substantially regardless of direct or indirect, and it is not always necessary to measure them. That is, if the rotation speed of the starter motor before being decelerated, or the physical quantity corresponding to the rotation speed is detected, the drive rotation speed is detected. Alternatively, even if the drive rotation speed is estimated from some physical quantity, it is assumed that the drive rotation speed is substantially detected. Similarly, the driven rotational speed is not limited to the rotational speed of the driven shaft, but may be the rotational speed of the engine with which the driven shaft is interlocked or a physical quantity corresponding thereto (ignition pulse interval, etc.). . In other words, the function of the rotational speed detection means is to have an operation that is mathematically or substantially equivalent to detecting the driving rotational speed and the driven rotational speed.
[0011]
Next, the rotation speed comparison means has an effect of comparing the drive rotation speed and the driven rotation speed. That is, it has the effect of comparing the drive rotational speed and the driven rotational speed, or detecting the rotational speed difference between the two rotational speeds. This action does not necessarily strictly indicate a comparison between the driving rotational speed and the driven rotational speed, but may be a mathematically, approximate, or substantially equivalent action.
[0012]
Finally, the energization stop determination means has an action of stopping energization to the starter motor when a predetermined condition is satisfied based on the comparison result of the rotation speed comparison means. That is, when it is determined that the engine has been started based on the comparison result of the rotation speed comparison means, it has the effect of quickly stopping energization of the starter motor.
[0013]
In other words, this means quickly stops energization of the starter motor when a predetermined condition sufficient to believe that the engine has started is satisfied based on the comparison result between the driving speed of the overrunning clutch and the driven speed. Be made. For example, a mechanical state such as whether the overrunning clutch is overrun (idle) is detected, and engine start determination is performed based on the result. Therefore, since the engine start determination is performed more directly than the conventional technique for indirectly determining the engine start from the physical quantity of the electric system, the reliability of the start determination is improved.
[0014]
As a result, the start of the engine is immediately determined, so that the energization to the starter motor is immediately stopped and the operation time of the starter motor is minimized. As a result, the starter motor can be stopped early and the starter motor drive time can be shortened while the engine is reliably started, so that the drive time is shortened and the life of the starter motor can be extended. . Further, when a speed reducer is disposed between the starter motor and the overrunning clutch, the life of the speed reducer can be extended as with the starter motor. Furthermore, although depending on the configuration of the overrunning clutch, the life of the overrunning clutch can be extended.
[0015]
In addition, noise and vibration due to the starter motor, the reduction gear, and the overrunning clutch can be completed in a short time, and a quieter driving environment can be provided. Similarly, the power consumed by the starter motor is reduced as much as the drive time of the starter motor is shortened, and a power saving action is also obtained.
[0016]
Therefore, according to the engine automatic starter of this means, there is an effect that the life of the starter motor and its peripheral machines can be extended while the engine is reliably started. In addition, when the engine is started, the duration of vibration and noise is reduced, and the power consumption of the starter motor is reduced.
[0017]
(Second means)
The second means of the present invention is the engine automatic starter according to claim 2. That is, in the first means described above, the rotation speed detection means measures a rotation signal from a rotation sensor installed on one of the starter motor and the drive shaft, and a power supply voltage applied to the starter motor. It is a detection means for detecting the drive rotational speed from either a voltage signal or a current signal obtained by measuring a current supplied to the starter motor.
[0018]
First, when the rotation speed detection means has a configuration for detecting the drive rotation speed based on a rotation signal from a rotation sensor installed on the starter motor or the drive shaft, it is directly proportional to the drive rotation speed or the drive rotation speed. The number of revolutions is measured. Therefore, according to this configuration, since the drive rotational speed is detected more precisely, the determination of the predetermined condition by the energization stop determination means is made more precisely and quickly. As a result, the highest reliability is obtained despite the cost of parts corresponding to the rotation sensor. Therefore, it is possible to stop energizing the starter motor in the shortest time while starting the engine more reliably. .
[0019]
Next, when the rotation speed detection means has a configuration for detecting the drive rotation speed based on a voltage signal obtained by measuring the power supply voltage applied to the starter motor, it is only necessary to install a voltage sensor, so that the parts cost is the lowest. It is. As a result, according to this configuration, there is an effect that the drive rotation speed can be detected at low cost.
[0020]
Finally, when the rotation speed detection means has a configuration for detecting the drive rotation speed based on a current signal obtained by measuring the current supplied to the starter motor, the drive rotation speed can be further increased while the component cost is relatively low. It becomes possible to estimate accurately. As a result, according to this configuration, there is an effect that it is possible to detect the rotational speed of the drive relatively inexpensively.
[0021]
By the way, the detection of the driving rotational speed has been described above. However, with respect to the driven rotational speed, a normal automobile is equipped with a rotation sensor for detecting the engine rotational speed, and the output of the sensor is taken into the control device. Can be easily detected. In the unlikely event that a rotation sensor for detecting the rotation speed of the rotation shaft of the engine is not provided, a new rotation sensor may be attached, or the rotation speed may be estimated from the interval between ignition pulses.
[0022]
As described above, according to this means, in addition to the effects of the first means described above, different effects can be obtained depending on the configuration.
[0023]
(Third means)
The third means of the present invention is the engine automatic starter according to the third aspect. That is, in the first means described above, the predetermined condition is one of the following first condition to third condition.
[0024]
The first condition is a condition that a state in which the rotational speed difference of the driven rotational speed with respect to the driving rotational speed exceeds a predetermined value is maintained for a predetermined time. Here, when the predetermined rotational speed difference is zero, the driven rotational speed only needs to be slightly higher than the driving rotational speed, and conversely, if the predetermined rotational speed difference is set with a significant magnitude, it is only that amount. The driven rotational speed is required to be higher than the driving rotational speed with the difference in rotational speed. Similarly, when the predetermined time is zero, it is sufficient that the driven rotational speed is instantaneously higher than the driving rotational speed by exceeding the predetermined rotational speed difference. Conversely, the predetermined time has a significant magnitude. If it is set, it is required that the high state is maintained for that time.
[0025]
In other words, when the engine starts and completes explosion (maintains its own operation), the engine speed increases rapidly, the driven shaft speed also increases, and the overrunning clutch enters the overrunning state (idling state). Become. Therefore, if it is confirmed that a predetermined overrunning state has been reached, the engine is no longer operating independently and the starter motor is idling, so compare the rotational speed between the drive speed and the driven speed. Thus, the start determination can be performed. Therefore, when the first condition is adopted as the predetermined condition, the effect of the first means described above can be obtained using an extremely simple logic by appropriately setting the predetermined rotational speed difference and the predetermined time. is there.
[0026]
The second condition is a condition that the driven rotation speed is equal to or greater than a predetermined value, and the number of rotations from the start of rotation of the driven shaft is equal to or greater than another predetermined value. Here, the number of rotations of the driven shaft can be easily counted from the integration of pulse signals obtained from a rotation sensor attached to the engine, the integration of ignition pulses, etc., so a new sensor is not particularly required. .
[0027]
That is, when starting the engine, the engine is driven at a sufficient number of revolutions so that the engine can operate independently even before a complete explosion, and the supply state of fuel or air-fuel mixture into the combustion chamber is only appropriate. If there is a number of rotations and proper ignition is performed in a gasoline engine or the like, the engine enters a self-sustaining operation state even if the starter motor is stopped. Therefore, even when the second condition is adopted as the predetermined condition, it is possible to make a reliable start determination using an extremely simple logic by appropriately setting the two predetermined values. The effect is obtained.
[0028]
The third condition is a condition that satisfies both the first condition and the second condition. That is, since the engine start determination is performed based on a larger number of items than the first condition or the second condition alone, the start determination is more reliable.
[0029]
Therefore, when the third condition is adopted as the predetermined condition, in addition to the effect of the first means described above, there is an effect that the engine can be started more reliably. In addition, there is also an effect that the energization to the starter motor can be stopped earlier to extend the life of the starter motor and the like, and the effect of the first means is further enhanced.
[0030]
(Fourth means)
A fourth means of the present invention is the engine automatic starter according to the fourth aspect. That is, in the first means described above, the control device causes the driven rotational speed to fall below a predetermined rotational speed within a predetermined time after the energization to the starter motor is stopped by the energization stop determining means. And a restart determining means for determining that restart is necessary and restarting energization of the starter motor. Here, when the restart determination means resumes energization of the starter motor, it is determined that the engine needs to be restarted because the engine whose rotational speed has fallen below a predetermined value is to be restarted. Shall be deemed to have been defeated.
[0031]
In this means, it is considered that the engine has been started once by the above-mentioned first means, and the engine rotation speed falls below a predetermined value due to an engine stall or the like after the starter motor is de-energized. Measures are taken. That is, according to this means, an engine whose rotational speed has decreased below a predetermined value without being completely exhausted can be restarted immediately, and the engine can be started more reliably. In particular, if the predetermined number of revolutions is not zero and is set to an appropriately large value, the shock at the time of re-engagement of the clutch is mitigated, so that the starter motor 3 can be prevented from being damaged by the shock and instantly. You can restart the engine.
[0032]
Therefore, according to this means, not only the effect of the first means described above is further enhanced, but also there is an effect that if the start is not complete, the restart is automatically performed without putting in a short hair.
[0033]
(5th means)
According to a fifth aspect of the present invention, there is provided the automatic engine starter according to the fifth aspect. That is, in the above-mentioned fourth means, the control device prohibits energization of the starter motor when it is determined that restart is required even if the restart determination means tries to restart a predetermined number of times. A restart abandonment means is further provided.
[0034]
In this means, the number of attempts to restart the engine is suppressed to an appropriate predetermined number by the restart abandoning means. Therefore, if there is a problem with the engine itself, its accessories, or the fuel system, and the engine cannot be started, energization of the starter motor is prohibited a predetermined number of times, and restart attempts are limited to the predetermined number of times. End. As a result, even when the engine cannot be started, the power supply system such as wiring and the starter motor are prevented from being overheated and damaged, and the battery is not wasted.
[0035]
DETAILED DESCRIPTION OF THE INVENTION
Embodiments of the automatic engine starter according to the present invention will be described in the following examples.
[0036]
[Example 1]
(Configuration of Example 1)
As shown in FIG. 1, the engine automatic starter according to the first embodiment of the present invention includes a control device 1 and a starter 2. The configuration of the starter 2 will be described first so that the configuration of the engine automatic starter according to the present embodiment can be easily understood.
[0037]
The starter 2 has a starter motor 3, a planetary speed reducer 4, an overrunning clutch 5, and a pulley 6.
[0038]
The starter motor 3 is a direct current motor driven by the battery 8. At the rear end of the starter motor 3, a frequency type rotation sensor 31 for measuring the rotation speed of the rotation shaft by pulse counting using a phototransistor is attached. A measurement signal from the rotation sensor 31 is supplied to a rotation speed detection unit 11 of the control device 1 described later. On the other hand, the rotating shaft protruding from the tip of the starter motor 3 is decelerated at a predetermined reduction ratio by the planetary reduction device 4 and drives the drive shaft 51 of the overrunning clutch 5.
[0039]
The overrunning clutch 5 is disclosed in Japanese Patent Application Laid-Open No. 9-172753 (Japanese Patent Application No. 8-200295). That is, the overrunning clutch 5 connects the drive shaft 51 that is decelerated and driven by the starter motor 3, the driven shaft 52 that is driven by the drive shaft 51 and should drive the engine rotation shaft 7, and both 51 and 52 are connected to each other. It has many sprags 53. The sprags 53 are arranged at equal intervals in the circumferential direction between the clutch inner ring forming one end of the drive shaft 51 and the clutch outer ring forming one end of the driven shaft 52. It is a member that relays torque to the clutch outer ring.
[0040]
When the rotational speed of the driven shaft 52 (that is, the rotational speed of the clutch outer ring) rises above a predetermined rotational speed (separated rotational speed) and torque transmission from the clutch inner ring in the forward rotational direction is not performed, the sprag 53 is subjected to centrifugal force. To leave the outer peripheral surface of the inner ring of the clutch. Once the sprag 53 is separated from the outer peripheral surface of the clutch inner ring, torque transmission from the drive shaft 51 to the driven shaft 52 is not possible until the rotation speed of the clutch outer ring (that is, the driven rotation speed) decreases by dividing the separation rotation speed. Disappear. When the driven rotational speed decreases by dividing the separated rotational speed, the sprag 53 comes into sliding contact with the outer peripheral surface of the clutch inner ring by the biasing action of the spring (not shown), and again from the driving shaft 51 to the driven shaft 52. Torque can be transmitted in the forward rotation direction.
[0041]
A pulley 6 is attached to the other end of the driven shaft 52 of the overrunning clutch 5, and the pulley 6 forms the tip of the starter 2. The pulley 6 is connected to a pulley 71 attached to the engine rotation shaft 7 via a belt. In addition, a rotation sensor 72 using a magnetic pickup is attached in the vicinity of the outer peripheral portion of the pulley 71 of the engine rotation shaft 7. Similarly to the measurement output of the rotation sensor 31, the measurement output of the rotation sensor 72 is also controlled by the control device 1. Is supplied to the rotation number detecting means 11.
[0042]
On the other hand, the control device 1 has a rotation speed detection means 11, a rotation speed comparison means 12, an energization stop determination means 13 and an energization determination means 16, and each of these means is realized mainly by digital calculation means. Yes.
[0043]
First, the rotation speed detection means 11 is a detection means for detecting the drive rotation speed of the overrunning clutch drive shaft 51 from the rotation signal from the rotation sensor 31 installed in the starter motor 3 described above. The rotation speed detection means 11 is a detection means for detecting the driven rotation speed of the overrunning clutch driven shaft 52 from the rotation speed of the engine rotation shaft 7 measured by the rotation sensor 72 described above. Here, the reduction ratio of the planetary reduction gear 4 is constant, and similarly, the reduction ratio between the pulley 6 on the starter 2 side and the pulley 71 on the engine side is also constant. The driving rotational speed and the driven rotational speed can be calculated. That is, the rotation speed detection means 11 detects the drive rotation speed and the driven rotation speed, and aligns both numerical data for the rotation speed comparison means 12.
[0044]
Next, the rotation speed comparison means 12 is a digital arithmetic means for comparing the magnitudes of the drive rotation speed and the driven rotation speed.
[0045]
The energization stop determination means 13 stops energization of the starter motor 3 when the simplest predetermined condition among the first conditions in the first means is satisfied based on the comparison result of the rotation speed comparison means. Has an effect. Here, the predetermined condition is that the driven rotational speed is higher than the driving rotational speed, that is, in the overrunning clutch 5, the rotational speed of the clutch outer ring is higher than the rotational speed of the clutch inner ring (that is, the overrunning clutch 5). The running clutch 5 is in an overrunning state). That is, the energization stop determination means 13 is based on the comparison result of the rotation speed comparison means 12, and the engine is started when the condition that the rotation speed difference of the driven shaft 52 with respect to the drive shaft 51 rises to a predetermined value or more is satisfied. And digital operation means for immediately stopping energization of the starter motor 3.
[0046]
Further, the energization determining means 16 outputs a relay drive current from a controller (ECU) (not shown) that starts energization of the starter motor 3 by the start command signal. Then, the switch 9 is closed and power is supplied from the battery 8 to the starter motor 3 so that the starter motor 3 is driven.
[0047]
When the energization stop determination unit 13 supplies the energization determination unit 16 with the energization stop command signal, the energization determination unit 16 stops the relay drive current and opens the switch 9 to stop energization of the starter motor 3. However, if the energization stop command signal is not supplied from the energization stop determination means 13 after the start of energization to the starter motor 3 after a predetermined time of about several seconds, the energization determination means 16 temporarily stops the relay drive current. Let This is for the purpose of preventing the starter motor 3 from overheating. Therefore, if a start command signal is given again after a predetermined time has elapsed, the energization determining means 16 resumes energization of the starter motor 3 in order to restart the engine. It has become.
[0048]
(Operation of Example 1)
Among the automatic engine starting devices of the present embodiment, the operation of the control device 1 (see FIG. 1) will be described in order along the control logic built in the control device 1 with reference to the flowchart of FIG. .
[0049]
First, in determination step S1, it is determined by the energization determination means 16 whether or not a start command signal from the ECU has been input in order to determine whether or not a start start condition is satisfied. If the start command signal is not input, the control logic of the control device 1 is completed immediately, and nothing is performed until restarting at a predetermined cycle. On the other hand, if a start command signal is input, the switch 9 is closed by the energization determining means 16 in processing step S2, and energization of the starter motor 3 is started.
[0050]
When energization of the starter motor 3 is started, the control logic proceeds to the next determination step S3, where the rotation speed comparison means 12 sets the rotation speed of the clutch outer ring (driven rotation speed) to the rotation speed of the clutch inner ring (drive rotation). It is determined whether or not the number has been exceeded. As long as the determination result is negative, the control logic repeats the determination step S3 many times, but if the driven rotational speed exceeds the driving rotational speed even once, it is determined that the engine has started, and the control logic performs the processing step. Proceed to S4. In processing step S4, the energization stop determination means 13 sends an energization stop command signal to the energization determination means 16, and the energization determination means 16 opens the switch 9 to stop energization of the starter motor 3.
[0051]
Once the engine is started, the overrunning clutch 5 is overrun, so that the starter motor 3 is not rotated by the engine and becomes an extra load. Then, after the engine is stopped according to the judgment of the ECU, the control logic completes a routine that is completed only through the judgment step S1 at predetermined time intervals until the start command signal is input to the control device 1 again from the ECU. repeat.
[0052]
In the engine automatic starter according to the present embodiment, the energization to the starter motor 3 is stopped by the above control logic. Therefore, for example, the following time change such as the number of revolutions occurs when the engine is started.
[0053]
First, time t ₀ When the switch 9 is closed and energization of the starter motor 3 is started, the rotational speeds of the clutch outer ring and the clutch inner ring driven by the starter motor 3 coincide with each other as shown in FIGS. . Then, after a certain number of cranking times, when both engine speeds rise to a certain level and the engine starts, the engine starts to rotate spontaneously and the time t ₁ Thus, the rotation speed of the outer ring of the clutch exceeds the rotation speed of the inner ring of the clutch. Then, the control device 1 detects that, determines that the engine has started, opens the switch 9, and stops energization of the starter motor 3. However, as shown in FIG. 4D, the time at which energization of the starter motor 3 is stopped by the time required for the processing time of the control device 1 and the response time of the switch 9 is the time t described above. ₁ Slightly later than.
[0054]
Then, the engine is started and enters a self-sustaining operation state, and the rotational speed of the clutch outer ring interlocked with the engine rotational speed rises again as shown in the second half of FIG. On the other hand, since the torque supply from the starter motor 3 is lost and the overrunning clutch 5 is disconnected, the rotation speed of the clutch inner ring linked to the rotation shaft of the starter motor 3 is again in the second half of FIG. As shown, quickly decelerate and stop. As a result, unlike the case where energization to the starter motor 3 is continued as shown by the broken line in the latter half of the figure, the rotation of the starter motor 3, the planetary speed reducer 4, the drive shaft 51, and the inner ring of the clutch is completed in a short time. In addition, the rotation speed of the starter motor 3 and the like does not become excessive in an unloaded state.
[0055]
As shown in FIG. 3D, the current flowing through the starter motor 3 is the time t. ₁ Immediately after, the power becomes zero, and the power of the battery 8 can be saved. As shown in the figure, while the starter motor 3 is energized, a large current that initially protrudes as an inrush current or a starting current flows. However, as the starter motor 3 rotates, the rotation speed increases. A corresponding back electromotive force is generated, and the current gradually decreases. Therefore, as will be described later, it is possible to implement a modification in which the timing of stopping energization of the starter motor 3 is determined by observing the current flowing through the starter motor 3. Similarly, as shown in FIG. 3C, the power supply voltage drops greatly when the starter motor 3 starts, but the power supply voltage gradually recovers as the rotation speed of the starter motor 3 increases. Therefore, as will be described later, it is possible to implement a modification in which the timing of stopping energization of the starter motor 3 is determined by observing the power supply voltage.
[0056]
(Effect of Example 1)
Since the engine automatic starter according to the present embodiment is configured as described above, according to the structural characteristics (see FIG. 1), the engine automatic starter can be broadly divided into the following three effects.
[0057]
The first effect is that the energization time of the starter motor 3 can be minimized and the life of the starter 2 can be extended.
[0058]
In other words, in this embodiment, when a predetermined condition sufficient to believe that the engine has started is satisfied based on the comparison result between the driving rotational speed of the overrunning clutch 5 and the driven rotational speed, the starter motor 3 is promptly supplied to the starter motor 3. Energization is stopped. That is, the control device 1 detects a mechanical state such as whether or not the overrunning clutch 5 is overrun (idle), and engine start determination is performed based on the result. Therefore, since the engine start determination is performed more directly, the reliability of the start determination is improved.
[0059]
As a result, when the engine is started, that fact is immediately determined, so that the energization of the starter motor 3 is also immediately stopped, and the starter motor 3 is kept from rotating more than necessary. Then, while starting the engine almost certainly, the energization to the starter motor 3 can be stopped early and the drive time of the starter motor 3 can be shortened, so the drive time is shortened and the life of the starter motor 3 is shortened. Can be extended. Further, the life of the planetary speed reducer 4 and the overrunning clutch 5 can be extended.
[0060]
Not only that, noise and vibration due to the starter motor 3, the planetary speed reduction device 4 and the overrunning clutch 5 can be completed in a short time, and a quieter driving environment can be provided. Similarly, as the driving time of the starter motor 3 is shortened, the power consumed by the starter motor 3 is also reduced, and a power saving action is also obtained.
[0061]
The second effect is that the detection of the drive rotation speed is accurately performed, so that the determination by the energization stop determination unit 13 is highly reliable.
[0062]
That is, the rotation speed detection means 11 detects the drive rotation speed based on the rotation signal from the rotation sensor 31 installed in the starter motor 3, so that the starter motor 3 is directly proportional to the drive rotation speed of the drive shaft 51. The number of rotations is precisely measured. Further, since the rotation speed of the engine rotation shaft 7 is also directly measured by the rotation sensor 72, the driven rotation speed of the driven shaft 52 of the overrunning clutch 5 is also measured sufficiently accurately. Therefore, since the detection of the driving rotational speed and the driven rotational speed is made more accurately, the determination of the predetermined condition by the energization stop determination means 13 is not only made precise, but also made very early. As a result, although the parts cost is increased by the rotation sensor 31, the highest reliability can be obtained, so that the starter motor 3 can be de-energized in the shortest time while starting the engine more reliably. effective.
[0063]
The third effect is that the control logic of the control device 1 is extremely simple, and hardware and software are inexpensive, so that the control device 1 can be provided at a very low cost.
[0064]
(Modification 1 of Example 1)
As a variation 1 of the present embodiment, the rotation speed detection means 11 is driven to rotate based on a voltage signal obtained by measuring a power supply voltage applied to the starter motor 3 instead of the rotation signal from the rotation sensor 31 of the starter motor 3. It is possible to implement an automatic engine starter that detects the number.
[0065]
In this modification, the rotation speed detection means 11 only needs to be equipped with a voltage sensor instead of the rotation sensor 31 so that the voltage signal obtained by measuring the power supply voltage applied to the starter motor 3 can be detected. The parts cost is the cheapest.
[0066]
Alternatively, as another alternative of this modification, the driving is performed based on a current signal obtained by measuring a current supplied to the starter motor 3 by a current sensor such as detecting a potential difference between both ends of a shunt resistor inserted in the circuit of the starter motor 3. It is possible to implement an automatic engine starter that detects the rotational speed.
[0067]
Then, since the rotation speed detection means 11 detects the drive rotation speed based on the current signal obtained by measuring the current supplied to the starter motor 3, the drive cost is relatively low compared with the rotation sensor 31, while driving. There is an effect that the rotational speed can be estimated relatively accurately.
[0068]
(Modification 2 of Example 1)
As a variation 2 of the present embodiment, it is possible to implement an automatic engine starter in which the predetermined condition used as the determination criterion for deenergization in the deenergization determination unit 13 is changed within the range of the first condition described above.
[0069]
The first condition is a condition that the state where the rotational speed difference of the driven rotational speed with respect to the driving rotational speed is higher than a predetermined value is maintained for a predetermined time. Here, unlike the first embodiment, if the predetermined rotational speed difference is not zero and is set with a significant magnitude, the driven rotational speed is required to be higher than the driving rotational speed with such a rotational speed difference. . Similarly, if the predetermined time is set to a significant value other than zero, it is required that the overrunning state be maintained for the predetermined time. According to this modification, by appropriately setting the predetermined rotational speed difference and the predetermined time, the engine can be more reliably used than in the first embodiment even if only a simple control logic having a slightly more complicated level than that in the first embodiment is used. There is an effect that can be started.
[0070]
(Other variations of Example 1)
As other modifications of the present embodiment, the following various types of engine automatic starters can be implemented.
[0071]
First, as means for detecting the driven rotational speed, the interval between ignition pulses may be measured and replaced with the rotation sensor 72. Also according to this modified embodiment, substantially the same effect as that of the first embodiment can be obtained.
[0072]
Next, the starter motor 3 is not limited to a DC motor, but may be other power means such as an AC motor. Further, the planetary speed reduction device 4 is not necessarily required and may be various types of speed reduction devices, and may be disposed at a position other than between the starter motor 3 and the overrunning clutch 5. It is not impossible even if it is done. Further, the overrunning clutch 5 need not be limited to the one of the configuration of the present embodiment, and various overrunning clutches or one-way clutches can be employed. In addition, as the torque transmission means from the starter 2 to the engine rotation shaft 7, belt drive is used in this embodiment, but other transmission means such as chain drive and gear drive may be used.
[0073]
[Example 2]
(Configuration of Example 2)
The engine automatic starter according to the second embodiment of the present invention has substantially the same configuration as that of the first embodiment as shown in FIG. However, the control logic of the energization stop determination means 13 is slightly different from that of the first embodiment, as will be described in the next section of the effect.
[0074]
(Effect of Example 2)
In this embodiment, the operation of the control device 1 and the starter 2 is almost the same as that of the first embodiment, but the control device 1 has the control logic described below as shown in FIG.
[0075]
First, steps S11 to S13 are the same as steps S1 to S3 of the first embodiment. However, after the overrunning state of the overrunning clutch 5 is detected in the determination step S13, a predetermined time is spent in steps S14 to S16 before the energization of the starter motor 3 is stopped in the processing step S17. That is, after the overrunning state of the overrunning clutch 5 is detected, the energization to the starter motor 3 is maintained for a predetermined time (for example, about 0.2 seconds or less) by the operation of the energization stop determination means 13. This is a measure taken for the purpose of ensuring a single start of the engine.
[0076]
That is, as shown in FIG. 5, the rotation speed of the clutch outer ring that is linked to the engine rotation speed pulsates during cranking. Therefore, if the power supply to the starter motor 3 is stopped immediately after the overrunning state of the overrunning clutch 5 is detected, the engine sometimes stops without starting and may need to be restarted. obtain. Therefore, if the engine is continuously driven by the starter motor 3 for a while after the overrunning state of the overrunning clutch 5 is detected as in the present embodiment, the engine can be started more reliably. .
[0077]
(Modification of Example 2)
The engine automatic starter of the present embodiment can also be implemented with modifications corresponding to the modifications of the first embodiment, and in addition to the functions and effects of the present embodiment, the functions and effects unique to each modification. Is obtained.
[0078]
[Example 3]
(Configuration of Example 3)
As shown in FIG. 1 again, the engine automatic starter according to the third embodiment of the present invention has substantially the same configuration as that of the first embodiment, but an ignition pulse signal is supplied to the control device 1 from the engine auxiliary machine. This is different from the first embodiment (not shown).
[0079]
Further, the control logic of the control device 1 is slightly different from that of the first embodiment. In other words, the predetermined conditions that serve as a reference for determining whether to stop energizing the starter motor 3 are that the driven rotational speed is higher than the driving rotational speed, that the ignition pulse signal is normally generated, and that the driven shaft rotates. The number of times is three or more other predetermined number of rotations. The effect produced by such control logic will be described with reference to a flowchart in the next section.
[0080]
(Effect of Example 3)
In this embodiment, the operation of the control device 1 and the starter 2 is almost the same as that of the first embodiment, but as shown in FIG. 6, the control device 1 has the control logic described below.
[0081]
That is, steps S21 to S23 are the same as steps S1 to S3 in the first embodiment. However, it differs from the control logic of the first embodiment in that determination steps S24 and S25 are added after the overrunning state of the overrunning clutch 5 is detected in the determination step S23.
[0082]
First, in determination step S24, it is determined whether or not the cylinder position is determined based on the cylinder determination signal.
[0083]
Next, in determination step S25, it is determined whether or not the number of engine rotations (cranking number) indicating how many times the crankshaft of the engine has rotated since the starter motor 3 is energized has reached a predetermined number of rotations. Is done. If the number of engine revolutions has reached a predetermined value, the control logic assumes that a normal air-fuel mixture is being supplied to the engine cylinder and proceeds to the next processing step S26. Return to S23.
[0084]
If the above determination steps S23 to S25 are cleared, the control logic determines that the engine has started, and the energization of the starter motor 3 is stopped in processing step S26. Here, before the energization is stopped, the following two conditions must be roughly divided. That is, the engine speed has increased to a predetermined speed suitable for starting, and the cylinder position has been determined, and a normal air-fuel mixture has been drawn into the cylinder and the air-fuel mixture can be regarded as burning. It is. If these conditions are met, the engine can be started very reliably even when the starter motor 3 is de-energized.
[0085]
Therefore, according to the engine automatic start device of the present embodiment, in addition to the effects of the first embodiment described above, there is an effect that the one-time engine start is further ensured. In addition, if the predetermined number of rotations and the predetermined number of rotations are set appropriately, the energization of the starter motor 3 can be stopped earlier than in the first embodiment, and the life of the starter 2 can be extended. There is also. As a result, the effect of the first embodiment is further enhanced depending on the setting of the predetermined rotation speed and the predetermined rotation speed.
[0086]
(Various variants of Example 3)
With respect to the engine automatic start device of the present embodiment, it is possible to carry out various modifications of the first embodiment, the second embodiment, and modifications corresponding to the respective modifications. Also according to each of these deformation modes, a unique effect can be obtained.
[0087]
[Example 4]
(Configuration of Example 4)
As shown in FIG. 7, the automatic engine starter according to the fourth embodiment of the present invention has the same configuration of the starter 2 as that of the first embodiment, but the configuration of the control device 1 is different from that of the first embodiment.
[0088]
That is, the control device 1 includes a restart determination unit 14 and a restart abandonment unit in addition to the rotation speed detection unit 11, the rotation number comparison unit 12, the energization stop determination unit 13, and the energization determination unit 16 that are substantially the same as those in the first embodiment. 15 is provided.
[0089]
After the energization to the starter motor 3 is stopped by the energization stop determination unit 13 after the energization stop determination unit 13 is stopped, the restart determination unit 14 determines that restart is necessary and determines that the starter motor 3 is to be restarted. Is a digital arithmetic means for resuming energization. When a command signal for restarting is output from the restart determination unit 14, the command signal passes through the restart abandonment unit 15 and reaches the energization stop determination unit 13 until the predetermined number of times is reached.
[0090]
On the other hand, the restart abandon means 15 has a counting function for counting the number of times the restart determination means 14 has issued a restart command signal. Then, the restart abandoning means 15 prohibits the energization determining means 16 from energizing the starter motor 3 when it is determined that restart is still required even if the restart determining means 14 attempts to restart a predetermined number of times. Is a digital arithmetic means for transmitting the signal.
[0091]
As described in the next section, the control logic of the control device 1 is different from that of the first embodiment.
[0092]
(Operation of Example 4)
In the engine automatic starter of the present embodiment, the control device 1 starts energization of the starter motor 3 in the switch 9 and stops it as follows in accordance with the control logic of the flowchart shown in FIG.
[0093]
That is, in this embodiment, when the control device 1 receives a start command signal from an external ECU (not shown), the control logic starts.
[0094]
First, in process step S31, the integer value D indicating the number of restarts is reset to zero, and preparations are made to execute control logic including engine restart. In the subsequent processing step S32, the starter motor 3 is energized and the engine is started until the overrunning clutch 5 is in an overrunning state, as in the control logic of the first embodiment (see FIG. 2). As soon as it is determined that the engine has started, the energization to the starter motor 3 is stopped, and the control logic proceeds to the next processing step S33.
[0095]
Next, in steps S33 to S36, due to the action of the restart determination means 14, the engine speed has decreased to a predetermined speed at which restart is required until the predetermined time C0 elapses after the engine is started. It is determined whether or not. Here, the predetermined number of rotations that serves as a reference for restarting is the separation rotation number of the overrunning clutch 5 described in the first embodiment (the boundary between whether or not the sprag can be separated from the outer peripheral surface of the clutch inner ring by centrifugal force). Is set appropriately lower than the rotation speed corresponding to the rotation speed).
[0096]
If the engine speed does not decrease to a predetermined speed that requires restarting until a predetermined time C0 elapses after the engine starts, the engine is completely in a self-sustaining operation state. The control logic is complete. On the other hand, if the engine speed has decreased to a predetermined speed that requires restarting after the engine has been started until a predetermined time C0, the control logic includes steps S37 and S38. Enter the routine.
[0097]
Then, the control logic returns to the processing step S32 again, and the starter motor 3 is energized at the stage where the engine speed has dropped below the predetermined speed, and the engine is restarted. Of the restart routine, steps S32 to S35 have already been described, and thus description thereof is omitted here.
[0098]
In the restart routine described above, the engine is repeatedly restarted up to the predetermined number of times D0 until it is determined in decision step S34 that the engine has completely entered the autonomous operation state. Meanwhile, if it is determined in the determination step S34 that the engine has completely entered the autonomous operation state, the control logic is completed there. Conversely, even if the engine restart is attempted up to the predetermined number of times D0, if it is not determined in decision step S34 that the engine has completely entered the autonomous operation state, the control logic abandons the engine restart and completes.
[0099]
(Effect of Example 4)
In the engine automatic starter according to the present embodiment, the restart determination means 14 and the restart abandonment means 15 are added to the control device 1 and the engine is started by the above-described control logic. Therefore, the following two effects are obtained.
[0100]
The first effect is that if the engine is not completely in a self-sustained operation state, it is automatically restarted without a short hair.
[0101]
That is, it is considered that the engine has been started once by the energization stop determination means 13, and after the energization to the starter motor is stopped, a countermeasure is taken against the case where the engine speed falls below a predetermined value due to engine stall or the like. It has been. That is, an engine whose rotational speed has decreased below a predetermined value without being completely exhausted can be restarted promptly by the determination of the restart determination means 14, and the engine can be started more reliably. In particular, since the predetermined number of revolutions is appropriately set to a large value, the starter motor 3 does not fail due to an impact when the clutch 5 is reengaged, and can be restarted instantaneously.
[0102]
Therefore, according to the engine automatic start device of the present embodiment, in addition to the effects of the first embodiment, there is an effect that if the engine is not completely started, the engine is automatically restarted without putting a short hair.
[0103]
The second effect is that not only the power supply system and the starter motor 3 can be prevented from being damaged due to overheating, but also the power depletion of the battery 8 can be prevented.
[0104]
In this embodiment, the restart abandon means 15 limits the number of attempts to restart the engine to an appropriate predetermined number D0. Therefore, if there is a problem with the engine itself, its auxiliary equipment, or the fuel system, and the engine cannot be started, energization of the starter motor 3 is prohibited a predetermined number of times. It ends with a predetermined number of times D0. As a result, even when the engine cannot be started, the power supply system such as wiring and the starter motor 3 are prevented from being damaged and the battery 8 is not wasted.
[0105]
(Various variations of Example 4)
As a modification of the present embodiment, it is possible to implement an engine automatic starter using the control logic of the second or third embodiment for the starter motor control in the processing step S32 of the control logic (see FIG. 8). In addition, it is possible to implement modified embodiments corresponding to the various modified embodiments of the first to third embodiments. According to any of the deformation modes, the operational effect according to the fourth embodiment can be obtained.
[Brief description of the drawings]
FIG. 1 is a block diagram showing a configuration of an engine automatic starter according to a first embodiment.
FIG. 2 is a flowchart showing a control logic of the control unit according to the first embodiment.
FIG. 3 is a set diagram showing temporal changes of respective items in the first embodiment.
(A) Time chart showing the rotational speed of the driven shaft of the clutch
(B) Time chart showing the rotational speed of the drive shaft of the clutch
(C) Time chart showing power supply voltage
(D) Time chart showing current flowing in starter motor
FIG. 4 is a flowchart showing a control logic of a control unit according to the second embodiment.
FIG. 5 is a time chart showing temporal changes in both rotation speeds in the second embodiment.
FIG. 6 is a flowchart showing a control logic of a control unit according to the third embodiment.
FIG. 7 is a block diagram showing a configuration of an engine automatic starter according to a fourth embodiment.
FIG. 8 is a flowchart illustrating a control logic of a control unit according to the fourth embodiment.
[Explanation of symbols]
1: Control device
11: Rotational speed detection means 12: Rotational speed comparison means
13: Energization stop determination means 14: Restart determination means
15: Restart abandonment means 16: Energization determination means
2: Starter
3: Starter motor 31: Rotation sensor
4: Reduction gear
5: Overrunning clutch
51: Drive shaft (directly connected to the inner ring of the clutch)
52: Driven shaft (directly connected to the clutch outer ring)
53: Sprag (Relay torque from clutch inner ring to clutch outer ring)
6: Pulley or pinion gear (directly connected to the driven shaft)
7: Engine rotation shaft
71: Pulley or ring gear 72: Pickup 73: Belt
8: Battery 9: Switch

Claims (4)

A starter motor,
A control device for operating and stopping the starter motor;
An overrunning clutch that connects a drive shaft that is driven by the starter motor and a driven shaft that is driven by the drive shaft to drive the engine rotation shaft;
In an engine automatic starter having
The controller is
A rotation speed detection means for detecting a drive rotation speed that is the rotation speed of the drive shaft and a driven rotation speed that is the rotation speed of the driven shaft;
A rotational speed comparison means for comparing the driving rotational speed with the driven rotational speed;
An energization stop determination unit that stops energization of the starter motor when a predetermined condition is satisfied based on a comparison result of the rotation speed comparison unit;
And to have,
The predetermined condition is
A first condition that a state in which the rotational speed difference of the driven rotational speed with respect to the driving rotational speed exceeds a predetermined value is maintained for a predetermined time;
A second condition that the driven rotational speed is equal to or greater than a predetermined value, and the number of rotations of the driven shaft is equal to or greater than another predetermined value;
Satisfying both of these conditions,
And wherein,
Automatic engine starter. The rotation speed detection means includes a rotation signal from a rotation sensor installed in at least one of the starter motor and the drive shaft, a voltage signal obtained by measuring a power supply voltage applied to the starter motor, and a start signal to the starter motor. Among the current signals obtained by measuring the current to be energized, is a detection means for detecting the drive rotational speed from any one,
The engine automatic starter according to claim 1. The control device determines that restart is necessary when the driven rotational speed falls below a predetermined rotational speed within a predetermined time after the energization to the starter motor is stopped by the energization stop determining means. A restart determination means for restarting energization of the starter motor;
The engine automatic starter according to claim 1. The control device further includes restart abandoning means for prohibiting energization of the starter motor when it is determined that restart is required even if the restart determination means tries to restart a predetermined number of times.
The engine automatic starter according to claim 3 .

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