KR102554933B1 - Cvt control method for vehicle - Google Patents

Abstract

The present invention includes a fixed ratio control step in which the controller maintains a constant target pulley ratio; a control state determination step in which the controller determines whether the pulley hydraulic control is defective by a difference between the actual pulley ratio and the target pulley ratio generated during the fixed ratio control step; When it is determined that the hydraulic pressure control of the pulley is poor, the controller includes a pressure increasing step of increasing the hydraulic pressure used for controlling the pulley by a predetermined additional pressure.

Description

Vehicle CVT control method {CVT CONTROL METHOD FOR VEHICLE}

The present invention relates to a continuous variable transmission (CVT) control method of a vehicle, and more particularly, to a technique for preventing slip (SLIP) of a belt-type CVT.

The CVT, which uses a belt as a variator, transmits power to the belt between the drive pulley and the driven pulley, while changing the pulley ratio of the drive pulley and the driven pulley to continuously change the transmission ratio.

The change in the pulley ratio of the drive pulley and the driven pulley drives the drive pulley and the driven pulley by hydraulic pressure so that the effective diameter ratio formed by the drive pulley and the driven pulley in contact with the belt is varied, and to ensure a stable operating state of the CVT. To achieve this, precise hydraulic control of the driving pulley and the driven pulley is required.

However, as the mileage of the vehicle increases, the controllability of the solenoid valve of the hydraulic control device deteriorates or the controllability of the solenoid valve of the hydraulic control device increases due to the increase in foreign substances due to wear of internal parts of the CVT and the increase in foreign substances in the hydraulic system due to wear of the oil pump and valve body. If a drop in the actual output pressure or the like occurs, the controllability of the pulley deteriorates.

As described above, if the pulley is not properly controlled, the belt slips, and if the vehicle continues to run in this state, the belt and the pulley are damaged and ultimately the CVT fails.

The matters described as the background technology of the present invention are only for the purpose of improving the understanding of the background of the present invention, and should not be taken as an admission that they correspond to the prior art already known to those skilled in the art. It will be.

KR 1014696720000 B

The present invention provides smooth and stable shifting performance and driving reliability of the vehicle by securing stable operability of the CVT by preventing the belt slip of the CVT from occurring while the vehicle is running, and securing the durability of the CVT. Its purpose is to provide a method for controlling the CVT of a vehicle.

CVT control method of a vehicle of the present invention for achieving the above object is

A fixed ratio control step in which the controller maintains a constant target pulley ratio;

a control state determination step in which the controller determines whether the pulley hydraulic control is defective by a difference between the actual pulley ratio and the target pulley ratio generated during the fixed ratio control step;

a pressure increasing step in which the controller increases the hydraulic pressure used for controlling the pulley by a predetermined additional pressure when it is determined that the hydraulic pressure control of the pulley is poor;

It is characterized in that it is configured to include.

In the control state determination step, when the magnitude relationship between the target pulley ratio and the actual pulley ratio fluctuates more than a predetermined reference number of times during a predetermined time from the time when the difference between the target pulley ratio and the actual pulley ratio is equal to or greater than a predetermined reference value, the pulley hydraulic pressure It can be judged that the control is poor.

When the target pulley ratio fluctuates during the reference time and a plurality of fixed ratio control steps are performed, the number of changes in the magnitude relationship between the target pulley ratio and the actual pulley ratio is determined by summing the number of changes in each fixed ratio control step. can be compared with recovery.

When the simulated shift control of the CVT is performed, the main gear section may be determined as the fixed ratio control step.

In addition, the CVT control method of a vehicle according to the present invention,

When the simulated shift control of the CVT is performed, during each popular gear section of the simulated shift belonging to a predetermined reference time, the difference between the target pulley ratio and the actual pulley ratio is equal to or greater than a predetermined reference value and the relationship between the magnitude of each other exceeds the predetermined reference number of times. When it is changed, it is characterized in that the hydraulic pressure used for controlling the pulley is increased by a predetermined additional pressure.

The present invention provides smooth and stable shifting performance and driving reliability of the vehicle by securing stable operability of the CVT by preventing the belt slip of the CVT from occurring while the vehicle is running, and securing the durability of the CVT. make it possible

1 is a configuration diagram of a CVT vehicle to which the present invention can be applied;
2 is a flowchart illustrating an embodiment of a CVT control method of a vehicle according to the present invention;
3 is a graph explaining an embodiment of a CVT control method of a vehicle according to the present invention;
4 is a diagram comparing a conventional CVT shift control method and a simulated shift control method.

Figure 1 is a schematic diagram showing the configuration of a CVT vehicle to which the present invention can be applied, the power of the engine (E) is transmitted to the drive pulley (DP) through the torque converter (TC), transmitted to the drive pulley (DP) The power is transmitted to the driven pulley (PP) through the belt (B), and is configured to be shifted and distributed to both drive wheels (W) through the differential (DF).

The controller CLR controls the hydraulic control device PA to change the effective diameter ratio of the drive pulley DP and the driven pulley PP by means of hydraulic pressure, so that the power from the engine E is applied to the vehicle's driving conditions. The transmission is shifted to an appropriate transmission ratio so that it can be provided to the driving wheel (W).

2 and 3, the CVT control method of a vehicle according to the present invention includes a fixed ratio control step (S10) of maintaining a target pulley ratio constant by a controller (CLR); a control state determination step (S20) in which the controller (CLR) determines whether the pulley hydraulic control is defective by a difference between the actual pulley ratio and the target pulley ratio occurring during the fixed ratio control step (S10); If it is determined that the pulley hydraulic pressure control is poor, the controller (CLR) is configured to include a pressure increasing step (S30) of increasing the hydraulic pressure used for the pulley control by a predetermined additional pressure.

That is, the performance of the fixed ratio control step (S10) is a basic prerequisite for performing the control state determination step (S20), and in a situation where the precondition is satisfied, it is determined whether the pulley hydraulic pressure control is good or not, and the pulley hydraulic pressure When it is determined that the control is poor, by increasing the substantially insufficient hydraulic pressure through the pressure raising step (S30), appropriate pulley control is induced to prevent the belt (B) from slipping.

In the control state determination step (S20), for a predetermined time from the time when the difference between the target pulley ratio and the actual pulley ratio is equal to or greater than a predetermined reference value, the magnitude relationship between the target pulley ratio and the actual pulley ratio fluctuates more than a predetermined reference number of times In this case, it is judged that the pulley hydraulic control is poor.

That is, while the CVT does not continuously change the transmission ratio and maintains a constant transmission ratio by the fixed ratio control step (S10), the controller (CLR) determines that the difference between the target pulley ratio and the actual pulley ratio is greater than or equal to the reference value. It is to determine whether or not there is an abnormality in the pulley hydraulic control by comparing the number of changes in the size relationship between the target pulley ratio and the actual pulley ratio with the reference number during the predetermined reference time from the point of time.

This is when the controller (CLR) controlling the CVT controls the drive pulley (DP) and the driven pulley (PP) to follow the target pulley ratio determined to be necessary according to the driving situation of the vehicle, substantially driving pulley (DP) and the driven pulley (PP) The actual pulley ratio realized by the pulley PP fails to properly follow the target pulley ratio and repeatedly generates a difference greater than the reference value, so that the actual pulley ratio centered on the target pulley ratio within the reference time, as illustrated in FIG. If it is determined that the sign of the value obtained by subtracting the actual pulley ratio from the target pulley ratio fluctuates more than the reference number of times by vibrating, the actual hydraulic pressure required for pulley control is insufficient and the pulley control is not properly performed, resulting in slip of the belt (B) that can be seen as occurring.

Therefore, the reference time, reference value, and reference number of times are designed by a number of experiments and analyzes in advance to the extent that the slip of the belt B according to the failure of the pulley control can be realistically determined according to the principle of the present invention as described above. that can be negatively determined.

On the other hand, as illustrated in FIG. 3 , the target pulley ratio to be controlled by the controller CLR during the reference time may vary according to the driving conditions of the vehicle. When the control step (S10) is performed, the number of fluctuations in the magnitude relationship between the target pulley ratio and the actual pulley ratio is calculated by summing the number of fluctuations in each fixed ratio control step (S10) and comparing it with the reference number. It can be used to determine the quality of control.

Of course, in this case, it would be desirable to exclude the change in the size relationship between the target pulley ratio and the actual pulley ratio at the moment when the target pulley ratio is changed from the determination of the quality of the pulley hydraulic control for more accurate determination.

Meanwhile, when the simulated shift control of the CVT is performed, the main gear section is determined in the fixed ratio control step (S10).

The simulated shift control is a control in which the CVT simulates the shift in a conventional stepped transmission and keeps the pulley ratio constant for a certain section to change the pulley ratio (=shift ratio) in a stepwise manner. It is popular in such simulated shift control. The gear section refers to a section in which a pulley ratio (strictly, a target pulley ratio) is constantly fixed, such as a section in which transmission gears are engaged in a stepped transmission to form a constant transmission ratio.

The left side of FIG. 4 exemplifies the pulley ratio control of the conventional basic CVT, not the simulated shift control, and illustrates that the target pulley ratio continuously changes, and in such a continuous change of the target pulley ratio, the actual pulley ratio Even when it is possible to infer that the slippage of the belt (B) is occurring by repeatedly and significantly changing the ratio in the vicinity, it is difficult to accurately count the change in the magnitude relationship between the target pulley ratio and the actual pulley ratio, and in this case It shows the difficulty of judging the quality of the pulley control.

In contrast, the right side of FIG. 4 illustrates a situation in which this simulated shift control is being performed, and since the target pulley ratio changes in a stepwise manner and maintains a constant target pulley ratio in a certain section, in contrast to this, the change in the actual pulley ratio is described above. By monitoring in the same way as in the present invention, it is possible to determine the quality of pulley control relatively accurately.

Of course, as described above, in the situation where the simulated shift control of the CVT is performed, the present invention is implemented by considering the popular gear section as the fixed ratio control step (S10), and when the simulated shift control is not basically performed, the controller (CLR ) may implement the present invention by fixing the target pulley ratio for a certain period of time and performing the fixed ratio control step (S10).

For reference, the controller (CLR) will be able to obtain the actual value of the actual pulley ratio by the number of rotations of the driving pulley (DP) and the number of rotations of the driven pulley (PP), and the additional pressure will be used in a number of experiments and analyses. In a situation where slip of the belt (B) is caused by poor pulley control, it can be appropriately set according to how much the hydraulic pressure used to control the belt (B) can be prevented from slipping the belt (B).

On the other hand, as another embodiment of the present invention, when the simulated shift control of the CVT is performed, during each popular gear section of the simulated shift belonging to a predetermined reference time, the difference between the target pulley ratio and the actual pulley ratio is greater than or equal to a predetermined reference value. When the relationship between magnitude and magnitude varies more than a predetermined standard number of times, the hydraulic pressure used for controlling the pulley may be increased by a predetermined additional pressure.

That is, in the above embodiment, the reference time starts from the case where the difference between the target pulley ratio and the actual pulley ratio is greater than or equal to the reference value, and thereafter, the number of changes in the size relationship regardless of the size of the difference between the target pulley ratio and the actual pulley ratio. However, in this embodiment, the difference between the target pulley ratio and the actual pulley ratio is more than the reference value, and at the same time, the case where the size relationship fluctuates more than the reference number during the reference time is considered as defective pulley hydraulic control. This is to make it more difficult to determine the pulley hydraulic control failure.

Although the present invention has been shown and described in relation to specific embodiments, it is known in the art that the present invention can be variously improved and changed without departing from the technical spirit of the present invention provided by the claims below. It will be self-evident to those skilled in the art.

E; engine
TC; torque converter
DP; driving pulley
CLR; controller
B; belt
PP; driven pulley
D-F; differential
W; drive wheel
PA; hydraulic control device
S10; Fixed cost control stage
S20; Control state judgment step
S30; pressure rise step

Claims (5)

A fixed ratio control step in which the controller maintains a constant target pulley ratio;
a control state determination step in which the controller determines whether or not the pulley hydraulic control is defective by a difference between the actual pulley ratio and the target pulley ratio generated during the fixed ratio control step;
a pressure increasing step in which the controller increases the hydraulic pressure used for controlling the pulley by a predetermined additional pressure when it is determined that the hydraulic pressure control of the pulley is poor;
It is composed of,
When the simulated shift control of the CVT is performed, the main gear section is determined as the fixed ratio control step.
CVT control method of a vehicle, characterized in that. The method of claim 1,
In the control state determination step, if the magnitude relationship between the target pulley ratio and the actual pulley ratio fluctuates more than a predetermined reference number of times during a predetermined reference time from the time when the difference between the target pulley ratio and the actual pulley ratio is equal to or greater than a predetermined reference value Determining that pulley hydraulic control is poor
CVT control method of a vehicle, characterized in that. The method of claim 2,
When the target pulley ratio fluctuates during the reference time and a plurality of fixed ratio control steps are performed, the number of changes in the magnitude relationship between the target pulley ratio and the actual pulley ratio is determined by summing the number of changes in each fixed ratio control step. compare to return
CVT control method of a vehicle, characterized in that. delete When the simulated shift control of the CVT is performed, during each popular gear section of the simulated shift belonging to a predetermined reference time, the difference between the target pulley ratio and the actual pulley ratio is equal to or greater than a predetermined reference value, and the magnitude relationship between them is equal to or greater than the predetermined reference number of times. If it fluctuates, increasing the hydraulic pressure used to control the pulley by a predetermined additional pressure
CVT control method of a vehicle, characterized in that.

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