JPH09112589A - Auto clutch controller - Google Patents

Abstract

PROBLEM TO BE SOLVED: To prevent clutch slip and starting shock by judging whether a clutch engaging quantity is suitable or not on the basis of the engine speed and input shaft revolutions, and if found unsuitable; correcting the engaging quantity determined by a clutch engaging quantity determining map using an engaging quantity correction map. SOLUTION: An A/T controller 5, which inputs output signals from an accelerator sensor 1, a gear position detecting switch 11, an input shaft revolution sensor 19, a clutch stroke sensor 20 and the like, calculates engine acceleration based on a detected signal from an engine speed sensor 18 when a vehicle is in a starting action and when a clutch is judged to be on the engaging side from a judgment halfway clutch point 18. When the engine speed is faster than a first set engine speed N1 , the engine speed difference between the engine speed and the input shaft revolution is successively checked whether it is larger than a second set engine speed difference N2 . If it is yes and there is a clutch 9 slip, an engaging correction quantity is found from an engaging quantity correction map and the clutch engaging quantity is corrected.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION The clutch of an auto clutch vehicle is controlled by a clutch actuator, and the present invention relates to an auto clutch control device in which a method of controlling a clutch engagement amount at the time of starting is improved.

[0002]

2. Description of the Related Art The clutch control of a vehicle is performed by a clutch pedal in a manual vehicle, but is performed by a clutch actuator controlled by a clutch control signal from a controller in an auto clutch vehicle.

FIG. 5 is a diagram showing a vehicle drive unit in which a conventional automatic clutch control device is incorporated. In FIG. 5, 1 is an accelerator sensor, 2 is a gear shift command device, 3 is a brake switch, 4 is a clutch engagement amount determination map, 5 is an automatic clutch controller, 5-1 is a memory, 7 is an engine control actuator, and 8 is an engine. , 9 is a clutch, 10 is a transmission, 11 is a gear position detection switch, 12 is a gear shift unit, 13 is a solenoid valve, 14 is a drive shaft, 15 is a vehicle speed sensor, 16 is an air pipe, 17 is an air tank, 18 is an engine rotation sensor, 1
9 is an input shaft rotation sensor, 20 is a clutch actuator, 21 is a clutch stroke sensor, 22
Is a solenoid valve. Although the clutch engagement amount determination map 4 is stored in the automatic clutch controller 5 in FIG. 5, it may be stored in a storage means outside the automatic clutch controller 5.

The outline of the operation is as follows. The engine control actuator 7 controls the fuel injection amount of the engine according to the control signal from the automatic clutch controller 5. Therefore, since the engine speed is also controlled by this, the engine control actuator 7 is also a speed control actuator. When the shift command signal is output from the shift command device 2, the automatic clutch controller 5 issues a control signal to the solenoid valve 13 to shift to the target gear. The solenoid valve 13 is provided from the air tank 17 to the gear shift unit (shift actuator).
Control air to 12 and shift gears in transmission 10. The gear position detection switch 11 detects the current gear position.

When controlling the clutch 9, first, a clutch control signal is sent from the automatic clutch controller 5 to the solenoid valve 22. The solenoid valve 22 controls air from the air tank 17 to the clutch actuator 20, and controls disconnection and engagement of the clutch. The magnitude of the clutch stroke is detected by the clutch stroke sensor 21.

The control of the clutch engagement amount at the time of starting (in other words, the control of the clutch stroke) is performed according to the clutch engagement amount determination map 4 stored in advance in the automatic clutch controller 5. FIG. 3 is a diagram showing an example of such a clutch engagement amount determination map. FIG. 3 (a) shows the clutch stroke control signal amount determined in correspondence with the accelerator opening, FIG. 3 (b) shows the clutch stroke control signal amount determined in correspondence with the engine speed, and FIG. ) Indicates the clutch stroke control signal amount determined in correspondence with the input shaft rotation speed. When starting, the clutch stroke is controlled by the sum of the clutch stroke control signal amounts obtained from these maps.

The initial value S _N of the clutch stroke control signal amount shown in FIG. 3B, when the transmission is in neutral and the clutch is advanced in the contact direction, the input shaft starts to rotate at a predetermined rotation speed. It is a clutch stroke control signal amount corresponding to the clutch position. This point is called the neutral learning point because the auto clutch controller 5 is adapted to determine (ie learn) this clutch position each time the transmission is made neutral.

Even if the clutch is controlled to the neutral learning point with the transmission in the traveling gear, the driving force for actually driving the vehicle is not transmitted because the clutch engagement force is small. Usually, the point where the transmission of the actual driving force is started is set in advance as the half-clutch point.
It is set as a point on the contact side by a certain clutch stroke from the neutral learning point.

At the time of starting, the clutch is first advanced to the half-clutch point, and then the clutch is completely engaged.
Since there is no substantial engagement at any position from the clutch complete position to the neutral learning point, it is often done to position the neutral learning point as the clutch engagement control start position. .

(Prior Art) As conventional literature concerning clutch control of an auto clutch vehicle, there are, for example, Japanese Patent Laid-Open No. 60-1450 and Japanese Patent Laid-Open No. 61-119440. The technique disclosed in Japanese Patent Laid-Open No. 60-1450 is a technique for changing the clutch control in response to wear of the clutch, and the slip ratio between the flywheel in the clutch and the clutch disc is 100 for reference of the control. When the clutch stroke, which is%, is advanced in the contact direction from the complete position,
This is for learning about the case of advancing in the disconnection direction from the complete contact position.

The technique disclosed in Japanese Patent Laid-Open No. 61-119440 is a technique for preventing a start shock if the load is light at the time of starting, and a delay in the start of traveling if the load is heavy. In this technology, the point where the input shaft starts to rotate with the transmission unloaded (neutral) and the point where the input shaft starts to rotate when the transmission is loaded (in the running gear) are calculated, and the clutch plate The "weighted averaging process" is performed according to the worn state and the vehicle weight at that time to find the point where the clutch starts to be engaged.

[0012]

[Problems to be solved by the invention]

(Problem) When the clutch is out of normal condition (eg,
When the clutch is normal, the neutral learning point fluctuates as compared with the case where the clutch is normal. Since the half-clutch point is set with the neutral learning point as a reference, it changes with the variation of the neutral learning point. On the other hand, the actual driving force is not transmitted unless the clutch plate is pressed firmly to some extent, so the actual driving force transmission point does not change as much as the neutral learning point. Therefore, the half clutch point set in the automatic clutch controller 5 and the actual driving force transmission point do not match.

As a result, the automatic clutch controller 5
However, when the clutch is controlled to the set half-clutch point, the clutch engagement amount may be too small or too large. If the amount is too small, the clutch slip will be large, the clutch will be damaged, and the engine will fly up. If too much,
A shock (starting shock) is given to the vehicle, and smooth starting cannot be performed. An object of the present invention is to solve such a problem.

[0014]

In order to solve the above-mentioned problems, in the present invention, in an automatic clutch control device in which a clutch is automatically controlled by a clutch actuator,
An engine speed sensor, an input shaft speed sensor, a means for storing a clutch engagement amount determination map, a means for storing an engagement amount correction map, and clutch engagement based on the detected engine speed and input shaft speed. If the amount is appropriate, and if it is determined to be inappropriate, the engagement amount correction map corrects the engagement amount determined in the clutch engagement amount determination map to control the clutch actuator. It is decided to have a control means to do so.

(Outline of operation) At the time of starting, the clutch engagement amount is first determined by the clutch engagement amount determination map as in the conventional case. The clutch engagement amount is determined by the engagement amount correction map while monitoring the engine acceleration. Correct the amount. Then, even if the half-clutch point set in the auto-clutch controller deviates from the actual half-clutch point, the clutch engagement amount will be appropriate and clutch slippage and starting shock will not occur. .

[0016]

Embodiments of the present invention will be described below in detail with reference to the drawings. FIG. 1 is a diagram showing a vehicle drive unit in which an automatic clutch control device of the present invention is incorporated. Reference numerals correspond to those in FIG. 5, and 6 is an engagement amount correction map. The parts having the same reference numerals as those in FIG. In addition, in FIG.
The engagement amount correction map 6 is used for the automatic clutch controller 5
Although stored in the auto clutch controller 5
You may make it memorize | store in an external storage means.

The engagement amount correction map 6 is a map as shown in FIG. The horizontal axis is the engine acceleration. Engine acceleration is the rate of change in engine speed (rpm / sec)
It is. This map is a map that gives a correction amount as to how much the engagement amount calculated in the clutch engagement amount determination map of FIG. 3 should be corrected when the engagement amount is too large or too small. The determination as to whether the amount is too large or too small will be described in detail later, but the engine speed, the input shaft speed, or the amount derived from them at that time is determined in accordance with a predetermined criterion.

In the present invention, the clutch control is not performed immediately with the engagement amount obtained from the clutch engagement amount determination map 4 at the time of start, but it is judged whether or not the correction is necessary. After making a correction using the map 6, the clutch is controlled. Next, the clutch control will be described in detail with reference to FIG. 2 while referring to FIG.

FIG. 2 is a flow chart for explaining the clutch engagement amount control method at the time of starting according to the present invention. Step 1 ... The clutch engagement amount is obtained from the clutch engagement amount determination map shown in FIG. This is the same as the conventional one. Step 2: Check whether you have pressed the accelerator pedal. This can be known from the signal from the accelerator sensor 1 of FIG. If you step on it, it means that you are starting.

Step 3: Check whether the clutch is on the contact side from the set half-clutch point. With the automatic clutch controller 5, if the clutch is controlled to the set half-clutch point, the actual driving force should start to be transmitted. If the set half-clutch point has not been reached yet, it is not necessary to correct the clutch engagement amount, so the process proceeds to END. Step 4 ... The engine acceleration is calculated based on the detection signal from the engine rotation sensor 18 in FIG.

Step 5 ... The calculated engine acceleration is
Check for a positive value. If it is positive, the engine speed is increasing, and if it is negative, it is decreasing. Step 6 ... In the case of plus, it is checked whether the engine speed is higher than the first set speed N ₁ . The first set rotational speed N ₁ is set in the memory 5-1 (the same applies to the set rotational speed appearing below). If the engine acceleration is positive, the clutch engagement amount is too small and the engine may blow up, so check this in this step. Therefore, the first set rotational speed N ₁ is set to a value that serves as a guide for determining whether or not the engine is about to rise.

Step 7 ... If the engine speed is higher than the first set speed N ₁ , the difference between the engine speed and the input shaft speed is the second set speed difference N.
Check if it is greater than ₂ . A large difference in the number of rotations means that the clutch is slipping, so the degree of slip is checked. As the second set rotational speed difference N ₂ , a rotational speed difference that is a criterion for determining whether the clutch slip is larger than the clutch slip that occurs during normal starting is set. The rotational speed difference is the second set rotational speed difference N ₂
If it is larger, the process proceeds to step 10 to correct the clutch engagement amount.

Step 8 ... If the engine acceleration is not positive in Step 5, it is expected that the clutch engagement amount is too large. In this case, the engine speed is checked whether third small or than the set rotational speed N ₃ of the. This is to check whether the engine speed that does not reach engine stalling is secured. If it has not decreased, there is no need to correct the clutch engagement amount, and the process proceeds to END.

Step 9 ... If the third set rotational speed N ₃ is lower than the third set rotational speed N ₃ , it is checked whether the input shaft rotational speed is lower than the fourth set rotational speed N ₄ . This is because the input shaft is rotating to the extent that it does not stall (in other words, whether the vehicle is moving to the extent that it does not stall).
This is to check. If the input shaft rotation speed is smaller than the fourth set rotation speed difference N ₄ , the process proceeds to step 10 to correct the clutch engagement amount.

As can be seen from the above description, step 5
The processes from 9 to 9 are processes for determining whether the clutch engagement amount is appropriate based on the engine speed and the input shaft speed. Each set is a criterion rotational speed N ₁ to N _4, depending on the type of engine or the like, appropriately determined.

Step 10 ... The engagement correction amount is obtained from the engagement amount correction map shown in FIG. 4, and the clutch engagement amount is corrected.
The horizontal axis of FIG. 4 is the engine acceleration, and the right side of the vertical axis is plus (+) and the left side is minus (-). Further, the vertical axis of FIG. 4 is the engagement correction amount, and the upper side and the lower side of the horizontal axis are plus (+) and minus (-), respectively.

Step 11 ... The clutch engagement amount is corrected by the engagement correction amount obtained from the map of FIG. When the correction is performed from step 7, since the engine acceleration is positive, a positive engagement correction amount can be obtained from the map of FIG. 4, and therefore the clutch engagement amount is corrected to be increased. On the contrary, if you proceed from step 9 and make corrections,
Since the engine acceleration is negative, a negative engagement correction amount can be obtained from the map of FIG. 4, so the correction is performed so as to reduce the clutch engagement amount.

[0028]

As described above, according to the automatic clutch control apparatus of the present invention, at the time of starting, the clutch engagement amount is first determined by the clutch engagement amount determination map as in the conventional case. Since the clutch engagement amount is corrected by the engagement amount correction map while monitoring, even if the half clutch point set in the auto clutch controller deviates from the actual half clutch point, the clutch engagement amount is It will be appropriate and will not cause clutch slippage or starting shock.

[Brief description of the drawings]

FIG. 1 is a diagram showing a vehicle drive unit in which an automatic clutch control device of the present invention is incorporated.

FIG. 2 is a flowchart illustrating a clutch engagement amount control method according to the present invention.

FIG. 3 is a diagram showing an example of a clutch engagement amount determination map.

FIG. 4 is a diagram showing an engagement amount correction map.

FIG. 5 is a diagram showing a vehicle drive unit in which a conventional automatic clutch control device is incorporated.

[Explanation of symbols]

1 ... Accelerator sensor, 2 ... Gear shift command device, 3 ... Brake switch, 4 ... Clutch engagement amount determination map, 5 ... Auto clutch controller, 5-1 ... Memory, 6 ... Engagement amount correction map, 7 ... Engine control actuator ,
8 ... Engine, 9 ... Clutch, 10 ... Transmission, 11 ... Gear position detection switch, 12 ... Gear shift unit, 13 ... Solenoid valve, 14 ... Drive shaft, 15 ... Vehicle speed sensor, 16 ... Air pipe, 17 ... Air tank, 18 ... Engine Rotation sensor, 19 ... Input shaft rotation sensor, 20 ... Clutch actuator, 21 ... Clutch stroke sensor, 22 ... Electromagnetic valve

Claims (1)

[Claims] 1. An automatic clutch control device in which a clutch is automatically controlled by a clutch actuator, an engine rotation sensor, an input shaft rotation sensor, a means for storing a clutch engagement amount determination map, and an engagement amount correction map. Means for determining whether the clutch engagement amount is appropriate based on the detected engine speed and the input shaft speed, and if it is determined to be inappropriate, the clutch engagement correction map is used to determine the clutch engagement amount. An automatic clutch control device comprising: a control unit that corrects the engagement amount determined by the amount determination map and controls the clutch actuator.