KR100774122B1 - The control method of safety for vehicle - Google Patents

Abstract

The present invention relates to a stability control method of a vehicle, and more particularly, to a stability control method of a vehicle for controlling steering and stability of the vehicle by controlling the braking pressure of the inner and outer wheels differently during turning of the vehicle. .

The conventional ESP system controls the braking pressure of the inner wheels of the front wheels or the rear wheels and the braking pressure of the outer wheels during turning of the vehicle equally, so that the driver's steering feeling is poor due to the inward yaw generated. It did not, there was a problem that the slip of the inner wheel is deteriorated the stability of the vehicle.

In addition, when the ESP system is operated, the stability of the vehicle is secured, but the driver's riding comfort is poor due to the unintentional braking pressure caused by the operation of the ESP system.

Accordingly, in the present invention, the vehicle stability control to control the braking pressure of the inner wheel and the outer wheel differently during turning of the vehicle to promote the steering and stability of the vehicle, and also to perform the above control process before the ESP system operates. Provide a method.

Vehicle attitude control, turning

Description

The control method of safety for vehicle

1 is a block diagram illustrating a vehicle stability control method of the present invention.

2 is a flow chart showing a vehicle stability control method of the present invention.

* Description of the symbols for the main parts of the drawings *

10: detector 20: microcomputer

21: vehicle speed calculation unit 22: yaw rate operation unit

23: turning driving judgment unit 24: yaw rate comparison unit

25: braking control unit 30: braking actuator

The present invention relates to a stability control method of a vehicle, and more particularly, to a stability control method of a vehicle for controlling steering and stability of the vehicle by controlling the braking pressure of the inner and outer wheels differently during turning of the vehicle. .

In general, the electronically controlled brake system effectively prevents slipping of the vehicle and obtains a strong and stable braking force.An anti-lock brake system (ABS) that prevents the sliding of the wheel during braking and the vehicle Brake Traction Control System (BTCS), which prevents slippage of driving wheels during sudden start or rapid acceleration, and anti-lock brake system and traction control in combination to control brake hydraulic pressure to keep the vehicle running stably. An electronic stability program (ESP) is disclosed.

ESP is a device that brakes itself or controls engine torque in dangerous driving situations to release the danger. If the ABS is effective only when the brakes are applied directly and only during braking, ESP is effective. It is a device that finds the best vehicle driving by itself without applying the brakes.

For example, if the driver is turning at a speed that is difficult for the driver to control, the ESP mounted on the vehicle may use appropriate wheels if the actual vehicle movement is greater than the stabilization threshold determined by using the vehicle movement amount obtained through the sensor and the road surface state obtained through the estimation. Control to ensure the stability of the vehicle.

In other words, when the rear wheel first reaches the adhesion limit between the tire and the road surface, an oversteer phenomenon appears. At this time, the ESP controls the front brake system to reduce the excessive turning moment generated by the front wheels. On the contrary, when the front wheel reaches the limit of adhesion between the tire and the road surface, understeer phenomenon occurs. At this time, the vehicle slides and goes beyond the normal turning radius. ESP is a system that controls all of these phenomena and maintains stability and steering by controlling the vehicle in the direction desired by the driver in emergency situations.                         

However, the conventional ESP system controls the braking pressure of the inner wheels of the front wheels or the rear wheels and the braking pressure of the outer wheels during turning of the vehicle in the same manner, so that the steering feeling of the driver is caused by the inward yaw generated at this time. This was not good, the slip occurred in the inner wheels there was a problem that the stability of the vehicle falls.

In addition, when the ESP system is operated, the stability of the vehicle is secured, but the driver's riding comfort is poor due to the unintentional braking pressure caused by the operation of the ESP system.

Accordingly, in the present invention, the vehicle stability control to control the braking pressure of the inner wheel and the outer wheel differently during turning of the vehicle to promote the steering and stability of the vehicle, and also to perform the above control process before the ESP system operates. Provide a method.

The present invention for achieving the above object is characterized in that it is performed in the step of determining whether the ESP mode, the turning driving control mode is not the ESP mode, the turning driving control mode is characterized in that it performs the turning driving control.

The determining of the turning driving control mode may include determining which one of the front and rear wheel braking controls, controlling whether one of the wheels is turning, and detecting the turning acceleration. When the value and the yaw rate error value is more than the predetermined reference value it is characterized in that it comprises the step of judging by the turning driving control.                     

In the step of performing the turning control, when the lateral acceleration value and the yaw rate error value are each greater than or equal to the set first reference value, the braking pressure of the inner wheels of the front and rear wheels is 70% to 80% of the braking pressure of the outer wheels. A first step of controlling by applying%;

If the lateral acceleration value and the yaw rate error value are each greater than or equal to the set second reference value, the braking pressure of the inner wheel cylinder of the rear wheel is controlled by applying 80% of the pressure of the outer wheel cylinder to perform the second step. It is characterized by.

The yaw rate error value may be a difference value from the measured yaw rate value calculated by the yaw rate calculator from the measured yaw rate value measured by the yaw rate sensor.

Each of the first reference values set is greater than the second reference value.

Hereinafter, a vehicle stability control method of the present invention will be described with reference to the accompanying drawings.

1 is a block diagram illustrating a vehicle stability control method of the present invention, Figure 2 is a flow chart showing a vehicle stability control method of the present invention.

First, the configuration will be described with reference to FIG. 1.

A wheel speed sensor 11 for detecting wheel speed at each wheel, a yaw rate sensor 12 for detecting the degree of turning of the vehicle, a steering angle sensor 13 for detecting a steering angle by the user, and Transverse accelerometer 14 for detecting side slip when turning and input signals output from the sensors 11, 12, 13 and 14 to detect and calculate turning driving and slip of the vehicle The microcomputer 20 performs overall driving control, and the brake actuator 30 performs braking control by inputting a braking control signal output from the microcomputer 20.

The microcomputer 20 may input a speed signal output from the wheel speed sensor 11 to calculate a traveling speed of the vehicle, and a driving speed and steering angle sensor calculated by the vehicle speed calculating unit 21. A turning drive judging unit 23 for inputting a steering signal output from 13 to determine whether the vehicle is currently turning or not; a yaw rate calculating unit 22 for calculating and outputting an optimum yaw rate through simulation; The yaw rate comparator 24 calculates an error value by comparing the yaw rate value detected by the rate sensor 12 with the yaw rate value calculated by the yaw rate calculator 22, and the yaw rate comparator 24. And a braking control unit 25 for inputting the yaw rate error value and the lateral acceleration value detected by the lateral acceleration sensor 14 and comparing the preset reference value with a preset reference value.

The control method will be described using the flowchart shown in FIG.

Determining whether the vehicle is in the ESP mode if slip occurs while driving; determining whether the wheel is braking control of the front wheel and the rear wheel if the vehicle is not in the ESP mode; and determining whether the vehicle is turning when the wheel is controlled. Steps,

When turning, it is determined whether the currently detected lateral acceleration value a _y and yaw rate error value ΔYaw are equal to or greater than each of the first reference lateral acceleration value a _y 1 and the first reference yaw rate error value ΔYaw1. In the judging step, if the set value is greater than or equal to the set value, the respective front and rear wheel braking pressures are controlled at a ratio of 70 to 80% of the outer wheel braking pressure, and if less than the set value, the second reference lateral acceleration value (a _y 2) and determining whether or not the second reference yaw rate error value (ΔYaw2) or more, and if the set value or more in the above step, the rear wheel brake pressure is controlled at a rate of 80% of the rear wheel brake pressure It consists of steps.

Hereinafter, the operation will be described in detail.

When the slip occurs while the vehicle is driving, the braking control unit 25 of the microcomputer 20 determines whether the slip occurs and determines whether to apply the ESP mode. That is, if the slip value is smaller than the preset ESP mode start slip value, the braking control unit 25 determines that the vehicle is not in the ESP control mode, and determines whether the partial braking control of one of the front wheel and the rear wheel of the vehicle is performed. In general, when the vehicle exhibits an understeer or oversteer tendency, the braking control unit 25 of the vehicle microcomputer 20 determines this and applies an appropriate braking pressure to the front or rear wheels of the vehicle to determine the understeer or oversteer. It is to prevent the phenomenon.

If it is determined that the partial braking control of one of the front wheel and the rear wheel, the turning driving determination unit 23 of the microcomputer 20 is present to the steering degree output from the steering angle sensor 13 and the vehicle speed output from the wheel speed sensor 11 It is determined whether the vehicle is turning, that is, cornering driving.

When it is determined that the vehicle is turning, the braking control unit 25 of the microcomputer 20 outputs the lateral acceleration value a _y and the yaw rate error value ΔYaw output from the lateral acceleration sensor 14 and the yaw rate comparator 24. Turning is performed to control the turning drive.

The lateral acceleration value a _y is a value detected by the lateral acceleration sensor 14, and the yaw rate error value ΔYaw is a measured yaw rate value and the yaw rate calculator 22 measured directly by the yaw rate sensor 12. The difference from the operation yaw rate value computed by.

That is, the lateral acceleration value a _y and the yaw rate error value ΔYaw are compared with the first reference lateral acceleration value a _y 1 and the first reference yaw rate error value ΔYaw1. _It is determined whether _y ) and the yaw rate error value ΔYaw are equal to or greater than each of the first reference values a _y 1 and ΔYaw1.

If the first reference value (a _y 1, ΔYaw1) or more, the braking control is performed at a rate of 70 to 80% of the inner wheel braking pressure of each of the front and rear wheels compared to the corresponding outer wheel braking pressure, respectively.

If the first reference value (a _y 1, ΔYaw1) is less than, the braking control unit 25 of the microcomputer 20 compares the second reference value (a _y 2, ΔYaw2) previously set.

The lateral acceleration value a _y and the yaw rate error value ΔYaw are compared with the second reference lateral acceleration value a _y 2 and the second reference yaw rate error value ΔYaw2, respectively. If a _y2 , ΔYaw2) is greater, the rear wheel brake pressure is controlled by 80% of the corresponding outer wheel brake pressure.

That is, the first reference value (a _y 1, ΔYaw1) and the second reference value (a _y2, ΔYaw2) is the second reference value, the first reference value (a _y 1, ΔYaw1) to a value that is set beforehand (a _y2, ΔYaw2) It is set larger than. In other words, the first reference value (a _y 1, ΔYaw1) is a value set in view of the more critical situations than a second reference value (a _y2, ΔYaw2).

As described above, in the present invention, the steering pressure and stability of the vehicle are controlled by controlling the braking pressures of the inner and outer wheels differently during the turning of the vehicle, and the control process is performed in advance before the ESP system operates. It improves steering and driving stability when turning and provides a comfortable driving environment.

Claims (4)

A wheel speed sensor for detecting wheel speed at each wheel, a yaw rate sensor for detecting the degree of turning of the vehicle, a steering angle sensor for detecting the steering angle by the user, and a horizontal side for detecting side slip when turning the vehicle. A yaw rate that calculates an error value by comparing an acceleration sensor, a yaw rate calculator that calculates an optimal yaw rate through simulation, and a yaw rate value detected by the yaw rate sensor and a yaw value calculated by the yaw rate calculator. Stability control of a vehicle including a microcomputer including a comparator and a brake control unit for outputting a brake control signal by inputting the yaw rate error value calculated by the yaw rate comparator and the lateral acceleration value detected by the lateral acceleration sensor In the method, Determining whether the vehicle is in a vehicle attitude control mode if slip occurs in the vehicle, determining whether the vehicle is in a vehicle driving control mode if the vehicle is in a vehicle driving control mode, and performing a driving control in the driving mode. The performing of the turning drive control may include determining whether the currently detected lateral acceleration value and yaw rate error value are equal to or greater than each of the set first reference lateral acceleration value and the first reference yaw rate error value. Each front wheel and rear wheel side brake pressure is controlled at a rate of 70 to 80% of the outside wheel brake pressure, and if it is less than the set value, it is determined whether the second reference lateral acceleration value and the second reference yaw rate error value are higher. And determining, if the setting value is equal to or greater than the set value, controlling the rear wheel inner brake pressure at a rate of 80% of the rear wheel outer wheel brake pressure. The method of claim 1, The determining of the turning driving control mode may include determining which one of the front and rear wheel braking controls, controlling whether one of the wheels is turning, and in the turning acceleration, the lateral acceleration sensor. And determining the turning driving control when the detected lateral acceleration value and the yaw rate error value calculated by the yaw rate comparison unit are equal to or greater than a predetermined reference value. delete The method of claim 1, And each of the first reference lateral acceleration value and the first reference yaw rate error value is set larger than the second reference lateral acceleration value and the second reference yaw rate error value.

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