JPH08304239A - Method for inspecting anti-lock brake - Google Patents

Abstract

PURPOSE: To judge the normal/abnormal state of an anti-lock brake having a special function by making the reference inverting value of braking time larger than a normal value and, at the same time, omitting the rotation variation of left and right rollers which occurs within a prescribed period of time after the connection starting time of the rollers from the objects to be judged. CONSTITUTION: The work of the general function of an anti-lock brake is restarted after left and right rollers are connected. When the work is restarted, the braking time of the brake becomes longer than that which obtained in the case where the general function continuously works and, consequently, the criterion value of the braking time for judgement is made larger than a normal value so as to prevent the occurrence of such a case than the brake is judged as abnormal even while the general function normally works. When the rollers are connected, in addition, the rotation variation of the rollers occurs due to the connection. Therefore, the rotation variation of the rollers which occurs within a prescribed period of time after the connection starting time is omitted from the objects to be judged so that the normal/abnormal state of the brake can be judged accurately based only on the rotation variation of the rollers caused by the work of the general function.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for inspecting an antilock brake having a function of releasing a brake when a rotational speed difference between left and right wheels exceeds a predetermined value.

[0002]

2. Description of the Related Art Conventionally, as a method for inspecting an anti-lock brake, Japanese Patent Application Laid-Open No. 4-305133 and Japanese Patent Application Laid-Open No. 4-3.
According to Japanese Patent No. 05134, a bench tester equipped with each roller for mounting each wheel of the vehicle is used to drive the vehicle with each wheel placed on each roller, and the brake is activated when a predetermined speed is reached. Then, a method is known in which the quality of the antilock brake is determined based on the braking time required for each roller to stop and the rotation fluctuation of the roller during the braking time. With this, the rollers are disconnected from each other when they reach a predetermined speed, and each roller is independently rotated while following each wheel during the brake operation. The braking state of the wheels can be individually detected.

[0003]

By the way, the antilock brake generally stops the increase of the brake pressure when the deceleration of the wheel exceeds the reference deceleration, and determines the rotation speed of each wheel. Compare the wheel reference speed during braking, which is determined based on the simulated vehicle speed, with the wheel speed, and when the wheel speed falls below the reference speed, reduce the brake pressure until the deceleration decreases to the reference deceleration. The control is performed such that the brake pressure is increased when the wheel speed exceeds the reference speed (see Japanese Patent Laid-Open No. 54-99879).

In addition to the general functions described above, the anti-lock brake has a difference in rotational speed between left and right wheels (mainly rear wheels) of a predetermined value or more in order to stabilize the posture of the vehicle during braking. There is a special function that releases the brake when it becomes. When the brake inspection of an automobile equipped with such an anti-lock brake is performed by the above-mentioned conventional method, the following problems occur.

That is, in the conventional method, since the brake inspection is performed in the state where each roller is independent, the difference in the rotational speed between the left and right wheels may occur due to the variation in the braking force with respect to each wheel. When the value exceeds the value, the above-mentioned special function is activated and the brake is released.In this case, when the vehicle is actually traveling, the left and right wheels will rotate at a speed equivalent to the vehicle speed when the brake is released. The difference decreases and the brake is applied again, but at the time of inspection,
Since the left and right wheels rotate independently on the independent left and right rollers respectively, it takes time until the rotational speed difference decreases, the brake remains released, and the brake inspection cannot be performed.

In view of the above points, the present invention is to provide an inspection method capable of determining whether the antilock brake is good or bad without any trouble even if the antilock brake has the above-mentioned special function. A second object is to provide an inspection method capable of determining the quality of the special function in addition to the quality of the general function of the antilock brake.

[0007]

In order to achieve the first object, the first invention of the present application has a special function of releasing the brake when the difference in rotational speed between the left and right wheels exceeds a predetermined value. Cars equipped with anti-lock brakes with the left and right wheels on the left and right wheels respectively were run, and when the specified speed was reached, the brakes were actuated until each roller stopped. In the inspection method that determines the quality of the anti-lock brake based on the braking time and the rotation fluctuation of each roller during the braking time, the rotation speed difference between the left and right rollers is detected after the operation of the brake is started. When is equal to or more than the predetermined value, the left and right rollers are connected to each other to continue the inspection, and at the time of the quality determination, the determination reference value of the braking time is made larger than the normal value,
In addition, it is characterized in that the fluctuation of the rotation of the rollers that occurs within a predetermined time from the start of the connection of the left and right rollers is excluded from the determination target. In order to achieve the second object, the second invention of the present application is equipped with an antilock brake having a special function of releasing the brake when the rotational speed difference between the left and right wheels exceeds a predetermined value. In a method of running an automobile that has left and right wheels on the left and right rollers, respectively, and activating the brakes when a predetermined speed is reached, inspecting the antilock brake, By using the means for producing the difference in the rotational speed of the rollers, the simulated condition satisfying the operation condition of the special function is created, and then the left and right rollers are connected to each other to continue the inspection, and it takes time until the rollers stop. Braking time,
Excluding fluctuations in the rotation of the rollers that have occurred within a predetermined time from the start of connecting the left and right rollers under the simulated state,
Whether the general function of the antilock brake is good or bad is judged based on the roller rotation fluctuation during the braking time, and whether the special function of the antilock brake is good or bad is judged based on the roller rotation fluctuation generated under the simulated state. Is determined.

[0008]

According to the first aspect of the invention, when the rotational speed difference between the left and right rollers (equal to the rotational speed difference between the left and right wheels) exceeds a predetermined value, that is, the brake is released by the action of the special function. At this time, since the left and right rollers are connected, the difference in rotational speed between the left and right wheels is reduced and the function of the special function is stopped. Therefore, although the operation of the general function of the antilock brake is temporarily interrupted, the operation of the general function is resumed after the roller connection. In this case, the braking time becomes longer than when the general function continues to work, so the judgment reference value of the braking time is made larger than the normal value, and it is judged that the general function is working normally but is defective. I'm trying not to. Further, when the left and right rollers are connected, fluctuations in the rotation of the rollers due to the connection occur. Therefore, the rotation fluctuation of the roller that occurs within a predetermined time from the start of the coupling is excluded from the determination target, and the pass / fail judgment can be accurately made based only on the rotation fluctuation of the roller caused by the operation of the general function of the antilock brake. I have to.

According to the second aspect of the invention, when the simulated state satisfying the operating condition of the special function is created, the brake is released if the special function works normally. Therefore, the quality of the special function can be accurately determined by determining whether or not the brake is released based on the fluctuation of the rotation of the roller under the simulated state. Also,
The operation of the general function of the anti-lock brake is interrupted under the simulated state and restarted after the left and right rollers are connected. Therefore, the braking time required for the rollers to stop and the rotational fluctuation of the rollers that occurred within a predetermined time from the start of the connection of the left and right rollers under the simulated state are excluded.
Whether the general function is good or not can be accurately determined based on the fluctuation of the rotation of the roller during the braking time. In addition, the judgment reference value of the braking time is
It is set to a large value in advance in consideration of interruption of the operation of general functions under the simulated state.

[0010]

1 shows a brake inspection device, which comprises a pair of left and right rollers 1 ₁ and 1 ₁ for front wheels and a pair of left and right rollers 1 ₂ and 1 ₂ for rear wheels. , a gear box 3 ₁ obtained by connecting respective roller 1 ₁ via a respective clutch 2 ₁ between the rollers 1 _1, 1 ₁ for the front wheels, rollers 1 ₂ for the rear wheels, 1 ₂
A gear box 3 _{2 in} which the rollers 1 ₂ are connected to each other via a clutch 2 ₂ is arranged between the two gear boxes 3 ₁ , 3 ₂
Are connected via a drive shaft 4, and when the vehicle is run by mounting the wheels on the rollers, the front wheels, which are the drive wheels, rotate to rotate the roller 1 ₁ , the clutch 2 ₁ , the gear box 3 _1, and the drive shaft 4. The rear wheels are made to rotate via the gear box 3 ₂ , the clutch 2 ₂ and the roller 1 ₂ .

Each of the rollers 1 ₁ and 1 ₁ is a pair of front and rear split rollers 1a connected through a belt 5 so as to rotate synchronously.
1b, the friction coefficient of the outer peripheral surface of both split rollers 1a, 1b is set to be large, and
a and 1b are set so that the rotational moments of inertia are equal to each other and the total rotational moment of inertia is slightly larger than the rotational moment of inertia of each wheel. I tried not to slip. Further, connecting the flywheel 6 to the rollers 1 _1, 1 ₂ of the rear split roller 1b, the divided roller 1b
And then interposed a torque meter 7 between the flywheel 6, it detects the rollers 1 _1, 1 ₂ of the deceleration as a torque,
The detection signal of the torque meter 7 was input to a monitor circuit 8 composed of a microcomputer, and an inspection described later was performed.

The front wheel rollers 1 ₁ and 1 ₁ are mounted on the fixed base 9.
Roller 1 ₂ for the rear wheels also 1 ₂ is provided on the moving freely slide board 10 before and after, a telescopic rear of the drive shaft 4 with a spline shaft 4b which is fitted to the sleeve 4a the structure and adapted to adjust the distance between the rollers 1 ₂ for the rear wheels and the roller 1 ₁ for the front wheels in accordance with the wheelbase of the motor vehicle by the movement of the slide board 10. Each of the clutches 2 ₁ and 2 ₂ is controlled to be turned on / off by a controller 11, and a signal from a speed sensor (not shown) that detects the rotation speed of each of the rollers 1 ₁ and 1 ₂ is input to the controller 11. ing.

[0013] In the brake test, when each wheel is traveling automobile placed on the rollers 1 _1, 1 _2, reaches a predetermined speed (e.g., 60Km / h), the rollers 1 _1, 1 ₂
The clutches 2 ₁ and 2 ₂ are turned off so that the rollers 1 ₁ and 1 ₂ are independently rotated, and the brake pedal is depressed in this state.

FIG. 2 shows a change in the wheel rotation speed V, a change in the wheel deceleration ν, and a brake pressure P when the rear wheel brake having a PCV provided in the hydraulic system is normally antilock-controlled. Change and torque T detected by the torque meter 7
And the change of. At the start of brake operation, brake pressure P
Is increased to a predetermined value Ps, the brake pressure is gradually increased by the action of PCV thereafter, and when the deceleration ν exceeds a predetermined set value νs, the increase of the brake pressure is stopped and the braking speed is calculated from the rotational speed of each wheel. When the wheel speed V drops below the reference speed Vs determined based on the pseudo vehicle speed, the deceleration ν is νs
The brake pressure is reduced until the value becomes below, and the wheel speed V becomes V
When it exceeds s, the brake pressure is increased, the above operation is repeated thereafter, and when the pseudo vehicle speed finally decreases to the predetermined low speed Vo, the antilock control is released and the wheels are braked in the normal brake state. Wheels and rollers stop. While the antilock control is being performed, the wheels are decelerated at a substantially constant deceleration that matches the deceleration characteristic of the reference speed Vs, and the torque T does not show a large peak change.
Further, when the roller is stopped, the elastic energy stored in the inertial system composed of the wheel, the roller and the flywheel is released, and the deceleration ν and the torque T temporarily drop below the zero level.

[0015] In the inspection process in the monitor circuit 8 is configured to detect when the torque T becomes _zero above a predetermined threshold level T as the operation starting time t ₀ of the brake, the time at which the torque T falls below the zero level Detected as the roller stop time t ₁ , calculate the braking time t from the time difference between t ₀ and t ₁ , and brake within the pass range between the lower limit value tL and the upper limit value tH determined according to the deceleration time of the reference speed. It is determined whether the time t has come. Further, the maximum torque Tmax generated within a predetermined set time ta (for example, 0.3 seconds) from t ₀ is detected, and whether Tmax is within a pass range between a predetermined lower limit value TL1 and upper limit value TH1. Further, it is determined whether or not the torque T generated after the elapse of ta is within a pass range between a predetermined lower limit value TL2 and an upper limit value TH2.

TL1 is a value corresponding to the deceleration νs at which the antilock control is started, TH1 is a value corresponding to the maximum deceleration at which the wheels are not locked, and TL2 and TH2 are based on the normal operating conditions of the antilock control. It is set to each value. Here, when the braking force is insufficient, FIG.
As indicated by the dotted line a in (d), the torque T is reached when ta has elapsed.
Does not increase to TL1, but when anti-lock control does not work and the brake pressure increases rapidly, the torque T exceeds TH1 before ta has elapsed and air is mixed in the hydraulic system, as indicated by the dotted line b. If a response delay occurs in the control of the brake pressure due to the above reasons, the fluctuation range of the torque becomes large, and the torque T cannot fall within the range between TL2 and TH2. Therefore, by performing the above determination, it can be determined whether or not the antilock control is normally performed.

By the way, the brake pressure of the left and right rear wheels is
Generally, it is controlled by a common hydraulic system, and in such a case, in order to stabilize the posture of the vehicle during braking, when the rotational speed difference between both rear wheels exceeds a predetermined value,
It is desirable to release the brakes on both rear wheels to reduce the speed difference. However, in addition to the above-mentioned general functions, the anti-lock brake has the special function of releasing the brakes of both rear wheels when the rotational speed difference between the left and right rear wheels exceeds a specified value. The following problems occur when inspecting the lock brake.

That is, during braking, each roller 1 ₁ ,
Since the connection between 1 and ₂ is released, the rear wheels rotate independently on the left and right rollers 1 ₂ for the rear wheels, and both rear wheels rotate due to variations in the braking force for both rear wheels. A speed difference may occur, and when this speed difference exceeds a predetermined value, the brakes on both rear wheels are released due to the function of the above special function. Since the difference in rotational speed is not reduced, the brake remains released and the brake inspection cannot be performed.

Therefore, in this embodiment, the difference in rotational speed between the left and right rollers 1 ₂ and 1 ₂ for the rear wheels is detected, and when this speed difference exceeds a predetermined value, the clutch of each roller 1 ₂ is detected. 2 ₂ is turned on, and the inspection is continued with both rollers 1 ₂ and 1 ₂ connected to each other. The details are as shown in FIG. 3. First, in step S1, it is determined whether or not the flag F is 1 (F is initially reset to 0), and when F = 0, the left and right steps are performed in step S2. It is determined whether or not the absolute value of the rotational speed difference ΔV between the rollers 1 ₂ and 1 ₂ is not less than a predetermined value ΔVs. When | ΔV | ≧ ΔVs, the timer is started in the step S3, and it is determined in the step S4 whether or not the timer time tm is equal to or longer than the predetermined time tms. tm is reset to 0 in step S5 when | ΔV | <ΔVs, and thus tm ≧ tms only when the condition of | ΔV | ≧ ΔVs continues for at least tms. And tm
When ≧ tms, it is determined in step S6 whether the rotational speed Vm of the high-speed roller of the left and right rollers 1 ₂ and 1 ₂ is equal to or higher than a predetermined value Vms (for example, 20 km / h).
Sets the flag F to 1 at step S7 when the ≧ Vms, to turn on the clutch 2 ₂ of the rollers 1 ₂ in step S8. When the clutch 2 ₂ is turned on in this way,
From the next time, go from step S1 to step S8,
The clutch 2 ₂ is maintained in the on state.

The above-mentioned special function generally works when the difference in rotational speed between the two rear wheels continues to be a predetermined value or more for a predetermined time (for example, 30 msec). Then, the above-mentioned tms is set so that the clutch 2 ₂ is turned on only when the special function is activated.

When Vm <Vms, both rollers 1
_{Since 2} and 1 ₂ are in the state immediately before stopping, it is useless to turn on the clutch 2 _2. Therefore, the clutch 2 ₂ is turned on only when Vm ≧ Vms. Incidentally, it is also possible to turn off the clutch 2 ₂ when omit step S1, was in a state of the special function does not work.

As described above, the clutch 2 ₂ is turned on,
The concatenation of both rollers 1 _2, 1 _2, reduces the rotational speed difference of the rear wheels, but the action of the general features of the anti-lock braking is resumed, the rollers 1 _2, 1 to ₂ of the connection time after and front wheel both rollers 1 _2, 1 ₂ for the rear wheels are accelerated by the roller 1 _1, 1 inertial force of the drive shaft 4 between ₂ for wheels, the deceleration of the rollers 2 _2, i.e., the torque T is, in FIG. 4 As shown, it may temporarily decrease and fall below TL2. In this state, since the general function of the anti-lock braking is determined to fail even working normally, except for the torque T generated from the connection start time of both rollers 1 _2, 1 ₂ within a predetermined time tb from the determination target Then, the quality determination is performed based on the torque T.
For example, as shown by a phantom line in FIG. 4, the torque waveform in tb is replaced with a straight line connecting torque values before and after tb, and the quality determination is performed.

Further, once the brake is turned off by the action of the special function, the braking time t becomes longer than the normal value, and when the special function acts, that is, the clutch 2 ₂ is actuated after the brake is activated. When it is turned on, at least the upper limit value tH which is the judgment reference value of the braking time t is set to a value which is + α larger than the normal value tHn (tH in FIG. 2 (d)), and the pass / fail judgment based on the braking time t is set. To do.

By doing so, even if the control function of the anti-lock brake works, it is possible to accurately determine whether the general function of the brake is good or bad.

In the above embodiment, the quality of the special function of releasing the brake due to the difference in rotational speed between the two rear wheels is not judged, but when the brake is activated, the rotation of the left and right rollers 1 ₂ and 1 ₂ is prevented. It is also possible to positively generate a speed difference, create a simulated state that satisfies the operation condition of the special function, and determine the quality of the special function.

For example, when the vehicle travels with the clutches 2 ₁ and 2 ₂ on and reaches a predetermined speed, the left and right rollers for the rear wheels are not turned off without turning off all the clutches 2 ₁ and 2 _2. Operate the brake with the clutch 2 _{2 of} 1 ₂ on.

According to this, since the one roller 1 ₂ is connected to the drive shaft 4 through the clutch 2 ₂ , the equivalent moment of inertia of the one roller 1 ₂ becomes large, and the one roller 1 ₂ there is hardly decelerated than the other roller 1 _2, even braking force is the same for both rear wheels, rear wheels rotational speed of one of the rear wheels on one of the rollers 1 ₂ and the roller said of the other The rotation speed of the rear wheel is faster than that of the rear wheel, the above-mentioned simulated state is created, and the brakes of both rear wheels are released.

In this case, the torque T changes as shown in FIG. 5, and when the predetermined time tc elapses from the first torque peak Tmax, the torque T decreases to the predetermined value TH3 or less and becomes substantially stable. Then, the clutch 2 ₂ of the other roller 1 ₂ is turned on, both rollers 1 ₂ and 1 ₂ are connected, and the inspection is continued. Both rollers 1 _2, 1 ₂ during connection, since the other roller 1 ₂ slow side is accelerated, the torque T of the roller 1 ₂ of the other side was temporarily reduced as indicated by the solid line in FIG. 5, also, since one of the rollers 1 ₂ of the high-speed side is decelerated, the torque T of the one roller 1 ₂ the temporarily increased as shown by a dotted line in FIG. 5, then the general function works is resumed both rollers 1 ₂ , 1 ₂ torque T
Both increase to a predetermined level and finally enter the normal brake state and stop. In the pass / fail judgment, whether or not the maximum torque Tmax generated within a predetermined time ta from the brake operation start time point t ₀ is within a passing range between TL1 and TH1 and within a period td until the above-mentioned special function starts to work. It is determined whether or not the torque T is within the acceptable range between TL2 and TH2, and whether or not the braking time t is within the acceptable range between tL and tH, and based on the integrated determination result of these, the general function The pass / fail judgment is made. Since the braking time t is inevitably lengthened by creating the above-mentioned simulated state, tL and tH are set to be larger than the values when inspecting without creating the simulated state.

Further, it is judged whether or not the torque T within the period te from the time point when the above tc has elapsed to the connection start time point of both rollers 1 ₂ and 1 ₂ is TH3 or less, and the special function The quality of is judged.

[0030] As the method of creating the simulation status is not limited to those described above, for example, a method of decelerating the roller 1 ₂ one of the left and right of the rear wheel after the start operation of the brake by the brake unit, not shown .

The inspection of the antilock brake having the special function of releasing the brake when the difference in rotational speed between the two rear wheels exceeds a predetermined value has been described above. The present invention can be similarly applied to the inspection of the anti-lock brake having a special function of releasing the brake when the above is reached.

[0032]

As is apparent from the above description, according to the present invention, even an antilock brake having a special function of turning off the brake when the rotational speed difference between the left and right wheels exceeds a predetermined value. The quality of the general function can be determined without any trouble, and the quality of the control function can be determined in addition to the quality of the general function.

[Brief description of drawings]

FIG. 1 is a plan view of an example of a brake inspection device used for carrying out the method of the present invention.

2A to 2D are graphs showing changes in wheel speed, wheel deceleration, brake pressure, and torque when the general function of the anti-lock brake works normally without interruption.

FIG. 3 is a flowchart showing a clutch control program during brake operation.

FIG. 4 is a graph showing changes in torque when the special function of the antilock brake is activated.

FIG. 5 is a graph showing changes in torque when a simulated state that satisfies the operating condition of the special function of the antilock brake is created.

[Explanation of symbols]

1 ₁ , 1 ₂ roller, 2 ₁ , 2 ₂ clutch,
7 Torque meter 8 Monitor circuit, 11 Controller

Claims (2)

[Claims] 1. An automobile equipped with an anti-lock brake having a special function of releasing the brake when the rotational speed difference between the left and right wheels exceeds a predetermined value, and the left and right wheels are respectively placed on the left and right rollers. The brakes are operated when the vehicle reaches a predetermined speed, and the brakes are activated to stop the anti-lock brakes based on the braking time it took for each roller to stop and the rotation fluctuation of each roller during the braking time. In the inspection method for determining the quality, the difference in the rotational speed of the left and right rollers is detected after the start of the operation of the brake. In addition, the judgment reference value of the braking time is set to be larger than the normal value, and the rotation fluctuation of the rollers that occurs within a predetermined time from the start of connecting the left and right rollers is judged. Inspection method of anti-lock brakes, except, characterized in that from. 2. A vehicle equipped with an anti-lock brake having a special function of releasing the brake when the rotational speed difference between the left and right wheels exceeds a predetermined value, by mounting the left and right wheels on the left and right rollers respectively. In the method of inspecting the anti-lock brake by activating the brake when it reaches a predetermined speed by using the means that causes a difference in the rotational speed of the left and right rollers when the brake is operated, After creating a simulated state that meets the operating conditions of the special function, and then connecting the left and right rollers to each other to continue the inspection, the braking time it took for the rollers to stop and the rollers under the simulated state and the left and right rollers. Of anti-lock brakes based on the roller rotation fluctuations during the braking time, excluding the roller rotation fluctuations that occurred within a predetermined time from the start of the Do quality functions determined, the simulated state based on the rotational fluctuation of the roller generated under determines the quality of the special features of the anti-lock braking, the inspection method of anti-lock brakes, characterized in that.