JPH029977B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to an anti-skid device for a vehicle, and more particularly to an anti-skid device that corrects a deviation in rear wheel speed of a vehicle to accurately perform anti-skid control during braking.

When a running vehicle suddenly brakes, the wheel speed rapidly decreases, but since there is a limit to the friction between the wheels and the road surface, slippage occurs between the wheels and the road surface, resulting in the skid phenomenon.

In order to prevent this skidding, in the past, the speeds of the front and rear wheels on the left and right sides of the vehicle were detected by respective sensors, and from these wheel speed data, the control circuit calculated the respective slip rates and optimal slip rates for the left and right front wheels and rear wheels. The brake force is controlled by calculating the slip rate and controlling the actuator attached to the brake hydraulic circuit etc. so that the slip rate approaches the optimum slip rate.

However, in such an anti-skid device,
The rear wheel speed sensor that detects the rear wheel speed is attached to the output shaft of the transmission or the propeller shaft side of the differential gear, and the rear wheel speed is detected via the differential gear. It is necessary to correct the actually detected rear wheel speed by using the speed variation due to the gear as a deviation, but the correction coefficient fixed in the control circuit is
When the detected rear wheel speed is multiplied and corrected, there are many errors, and it is necessary to change the correction coefficient for each vehicle body and each type of differential gear.

The present invention was developed in view of the above points, and uses an automatically calculated correction coefficient to correct the detected rear wheel speed to create accurate speed data, thereby enabling accurate brake control. The object of the present invention is to provide an anti-skid device that can perform the following steps. For this reason, when the vehicle is running at a constant speed above a certain speed within a certain acceleration/deceleration while driving straight without braking, the rear wheel speed is corrected based on the speed of each wheel detected by the sensor. The detected rear wheel speed is corrected by calculating a coefficient and then multiplying the rear wheel speed by a coefficient obtained by integrating and averaging the correction coefficient.

Embodiments of the present invention will be described below based on the drawings.

Figure 1 shows a schematic diagram of the anti-skid device.
FIG. 2 shows a block diagram of the electrical circuit.

Reference numeral 21 denotes a transmission of the automobile, and a rear wheel speed sensor 3 consisting of a rotor and an electromagnetic pickup is attached to the output shaft of the transmission. 3
It is connected to a differential gear 22 that is connected to a drive shaft 24 of No. 0. right front wheel 2
A right front wheel speed sensor 1 is attached to the axle of the left front wheel 29 to detect its speed, and a left front wheel speed sensor 2 is attached to the axle of the left front wheel 29 to detect its speed. Regarding the brake device, 25 is a brake pedal, and a stop switch 7 is attached to the brake pedal 25 as a brake detection means for detecting a braking state.The brake pedal 25 operates a master cylinder 26 to control brake hydraulic pressure by an actuator. and is configured to send it to a hydraulic control section.
The actuator used for anti-skid control by controlling the brake hydraulic pressure applied to the brake devices of the left and right front wheels 28, 29 and the rear wheel 30 includes a right front wheel actuator 15, a left front wheel actuator 16, and a rear wheel actuator 17. Each brake drive signal is separately received from a control circuit 20 to be described later, and the brake force of each of the left and right front wheels and rear wheels is controlled.

The control circuit 20 has a built-in microcomputer 11, and the right front wheel speed sensor 1, the left front wheel speed sensor 2, and the rear wheel speed sensor 3 shape and amplify pulse signals proportional to their respective wheel speeds using circuits 4, 5, 6.
A brake detecting means, such as a stop switch 7, is connected to send a signal indicative of a brake operation to the microcomputer 11 via a buffer circuit 9. Furthermore, as a result of arithmetic processing performed by the CPU in the microcomputer 11 based on a predetermined control program, the microcomputer 11 generates brake control for each wheel in order to bring the current slip rate of each wheel closer to the optimum slip rate. The signal passes through brake control drive circuits 12, 13, and 14 to a right front wheel actuator 15 that controls the right front wheel brake oil pressure, a left front wheel actuator 16 that controls the left front wheel brake oil pressure, and a rear wheel brake oil pressure. It is connected so as to be sent to the rear wheel actuator 17.

Next, in explaining an example of the operation of this anti-skid device, first, the flowchart shown in _FIG . The calculation routine will be explained in detail.

When the automobile starts running, this routine is executed by a predetermined timing signal, and first, in step 38, the register for integrating the correction coefficient K _R ' is reset and the stored data is cleared. Next, in step 39, each wheel speed data is taken in, and the right front wheel speed V _FR is calculated from the detection signal sent from the right front wheel speed sensor 1, and the left front wheel speed is calculated from the detection signal from the left front wheel speed sensor 2.
Then, _the rear wheel speed _VRO is calculated from the detection signal of the rear wheel speed sensor 3. Next, the process proceeds to determination step 40, where it is determined whether or not each wheel speed calculated in step 39 above is a certain value, for example, 40 km/h or more, and if the wheel speed is over a certain value, then The judgment is ``YES'' and the process proceeds to step 41.
If the wheel speed is below a certain value, go to step 39 again.
Return to In step 41, from the temporal changes in the respective wheel speeds V <sub>FR</sub> , V <sub>FL</sub> , and V <sub>RO</sub> calculated in step 39, the right front wheel acceleration/deceleration V〓 <sub>FR</sub> , the left front wheel acceleration/deceleration V〓 <sub>FL</sub> , and the rear wheel acceleration/deceleration V〓 <sub>RO</sub> are calculated respectively. and,
Proceed to judgment step 42 and check that the acceleration/deceleration of each wheel calculated in step 41 above, V〓 <sub>FR</sub> , V〓 <sub>FL</sub> , V〓 <sub>RO</sub> , is a constant acceleration/deceleration that can be regarded as almost constant speed running (for example, ±0.5 g).
A determination is made as to whether or not the acceleration/deceleration of each wheel is within the constant acceleration/deceleration, and if the acceleration/deceleration of each wheel is within the constant acceleration/deceleration, the determination is ``YES'' and the process proceeds to step 43, but if the acceleration/deceleration of each wheel does not exceed the constant acceleration/deceleration. If so, return to step 39 again. In step 43, a signal indicating a brake operation from the stop switch 7 is input, and a judgment is made as to whether or not the brake is being operated.If the brake is not being operated, the judgment is "NO", and the process then proceeds to step 44. On the other hand, if the judgment is ``YES'' because the brake is being operated, the process returns to step 39. These steps 40, 42, 43, and 44 determine whether or not the vehicle is in a steady straight-ahead running state in which each wheel is running at a constant speed.When the vehicle is in a non-braking straight-ahead running state, steps 45 and subsequent steps are performed. The correction coefficient K _R is calculated by the calculation.

That is, in step 45, the front right wheel speed V _FR calculated in step 41 and the front left wheel speed V _FL are added and divided by 2 to calculate the average front wheel speed V _F .
Next, in step 46, the ratio of the front wheel average speed _VF to the rear wheel speed _VRO calculated in step 41 is calculated as a correction coefficient _KR '. Then, proceed to step 47 to calculate the correction coefficient calculated in step 46 above.
K _R ′ is stored in the accumulation register so as to be added to the previous data, and the correction coefficient is accumulated. Next, in decision step 48, it is determined whether a predetermined number of samplings have been completed. That is, it is determined whether or not the correction coefficient K _R ' calculated by repeatedly executing steps 39 to 47 has been integrated a predetermined number of times n. When a predetermined number of correction coefficients K _R ' are accumulated in the accumulation register, a "YES" determination is made, and then step 49 is performed.
Proceed to step 39 if the answer is “NO”.
Returning to , the correction coefficient K _R ' is further sampled. In step 49, the integrated value of the correction coefficient K _R ' accumulated a predetermined number n times in the accumulation register is divided by n to calculate the average correction coefficient K _R .

In this way, the correction coefficient K _R for rear wheel speed correction accumulated and averaged by n samplings is:
It is temporarily stored in memory and used by multiplying the detected rear wheel speed to perform brake control when the brakes are applied, and corrects a deviation in the detected rear wheel speed caused by the differential gear 22.

Next, anti-skid control during brake operation will be explained with reference to the flowchart of FIG.
First, while the vehicle is running, the speed of each wheel is captured in step 50, and the front right wheel speed sensor 1 receives a speed signal for the right front wheel, the left front wheel speed sensor 2 receives a speed signal for the left front wheel, and then the speed signal for the rear wheel. A rear wheel speed signal is sent from the speed sensor 3 to the control circuit 20, and each speed data is taken into the microcomputer 11.
Then, in step 51, the rear wheel speed V _RO is multiplied by the above-mentioned correction coefficient K _R , and the rear wheel speed V _RO detected in step 50 is corrected to create the rear wheel speed V _R . In the next determination step 52, it is determined whether or not the vehicle is decelerating based on the wheel speeds taken in. If the vehicle is not decelerating, the process returns to step 50, and if it is decelerating, the process proceeds to step 53 where the wheel speed data is Virtual vehicle speed that decelerates at a constant deceleration from
V _B is calculated, and furthermore, in step 54, the optimum slip rate is calculated.

With the vehicle speed V _B and the optimum slip ratio calculated, the wheel speeds at this time are taken in again in step 55, and the right front wheel speed V _FR and the left front wheel speed are calculated.
Each data of V _FL and rear wheel speed V _RO is input,
In step 56, the rear wheel speed _VRO is multiplied by the correction coefficient _KR to calculate the corrected rear wheel speed _VR . next,
Proceeding to step 57, the slip rates S ₁ , S ₂ , and S ₃ for each wheel at this time are calculated as S ₁ = (V _B − V _R )/V _B S ₂ = (V _B − V _FR )/V _B S ₃ = (V _B − V _FL )/V _B , and further, in a judgment step 58, these slip rates S ₁ to _{S 3} are compared with the optimum slip rate calculated in step 54, and the slip rate S ₁ ~ _S3
“NO” when the slip rate has not reached the optimum slip rate.
When it is determined that this has been reached, the process returns to step 55, and when it has been reached, the process proceeds to step 59, where a brake release signal is issued. When the microcomputer 11 issues brake release signals for the left and right front wheels and rear wheels, each brake control drive circuit 1 in the control circuit 20
This signal is sent to the brake control drive circuits 12 to 14, and the brake control drive circuits 12 to 14 drive the actuators 15 to 17, whereby the hydraulic pressure in each brake hydraulic circuit is controlled to decrease, and the brakes of each wheel are loosened.

Next, in step 60, the wheel speed at this point is again taken in, and each speed data of right front wheel speed V _FR , left front wheel speed V _FL , and rear wheel speed V _RO is input, and in step 61, the rear wheel speed is inputted. Correction factor K _R to speed V _RO
is multiplied and the rear wheel speed is corrected. Next, the process proceeds to judgment step 62, where it is judged whether the speed of each wheel is accelerating or not, and the brake is released in response to the generation of the brake release signal in step 59, and the process proceeds to step 59.
If the speed of each wheel is accelerated compared to the speed detected in steps 55 and 56, the judgment is "YES" and the process proceeds to step 63.
Then, the slip ratio at this point is again calculated for the left and right front wheels and the rear wheel in the same manner as in step 57 above. Then, in step 64, the slip rate for each wheel calculated above is compared with the optimum slip rate calculated in step 54,
If the slip rate of each wheel has reached the optimum slip rate, the determination is ``YES'' and the process proceeds to step 65, where the brake release signal is turned off and the brake is activated. Then, in step 66, the time period during which the brake release signal was issued (used to calculate the optimum slip ratio) is calculated, and then the process returns to step 50, and this operation is repeated.
Anti-skid brake control is performed accurately.

As explained above, since accurate rear wheel speed data can be obtained according to the anti-skid device of the present invention, sufficient accuracy can be obtained in the anti-skid control performed based on this accurate data. Furthermore,
Since an accurate correction coefficient suitable for the vehicle body is automatically calculated, there is no need to set the correction coefficient for each vehicle body, and compatibility of the anti-skid device can be ensured.

[Brief explanation of drawings]

The figures show an embodiment of the present invention, in which Fig. 1 is a schematic diagram of the anti-skid device, Fig. 2 is a block diagram of the same electric circuit, Fig. 3 is a flowchart for calculating a correction coefficient, and Fig. 4 is an anti-skid control. This is a flowchart showing the following. 1... Right front wheel speed sensor, 2... Left front wheel speed sensor, 3... Rear wheel speed sensor, 7... Brake detection means, 15... Right front wheel actuator, 16...
Left front wheel actuator, 17... Rear wheel actuator, 20... Control circuit.

Claims (1)

[Claims] 1. A sensor that detects the wheel speed of the left and right front wheels and rear wheels, an actuator that controls the brake oil pressure of each wheel, and detection data from each of the above sensors is input, and a virtual vehicle speed is calculated during braking. At the same time, the slip rate and optimal slip rate are calculated for each wheel based on each wheel speed and the virtual vehicle speed,
and a control circuit for controlling the actuator so that the slip rate of each wheel approaches the optimum slip rate, wherein the anti-skid device is provided with a control circuit that controls the actuator so that the slip rate of each wheel approaches the optimum slip rate, and the anti-skid device is provided with a control circuit that controls the actuator so that the slip rate of each wheel approaches the optimum slip rate. When traveling at a constant speed, the correction coefficient for the rear wheel speed is calculated multiple times from the left and right front wheel speeds and the rear wheel speed detected by each of the sensors, and the calculated correction coefficients are integrated and averaged. An anti-skid device characterized in that the control circuit is configured to correct a deviation in rear wheel speed by using a correction coefficient as a correction coefficient and multiplying the rear wheel speed by the correction coefficient during braking.