JP4171495B2 - Vehicle stop determination method, electric parking brake control method, vehicle stop determination device, and electric parking brake control device - Google Patents

Description

  The present invention relates to a determination method and a determination device for determining stoppage of a vehicle such as an automobile, and an electric parking brake control method and an electric parking brake control device including such a determination method and determination device.

The electric parking brake drives a parking brake that performs braking when the vehicle is parked or stopped using an electric actuator such as a motor.
Since such an electric parking brake can be operated by an electric switch by a driver, labor is reduced with respect to an operation by a general manual lever or a foot pedal.

  Further, it has been proposed that the electric parking brake has a hill hold (hill holder) function. The hill hold function is a function that prevents the vehicle from moving by automatically operating the electric parking brake when the vehicle is stopped on a slope. In order to realize such a hill hold function, it is required to reliably determine whether the vehicle has stopped.

A vehicle is known that includes a vehicle speed sensor that detects the rotational speed of a wheel, and it is known that the output of the vehicle is also used to determine whether or not to stop the vehicle. However, such a vehicle speed sensor cannot accurately detect the vehicle speed at an extremely low speed immediately before stopping, and may not be able to measure when the actual vehicle speed is about 2 km / h or less, for example. Therefore, conventionally, the electric parking brake operates a timer when the detection value of the vehicle speed sensor becomes 2 km / h or less immediately before the vehicle stops, determines that the vehicle has stopped after a predetermined time has elapsed, and brakes. There is known a device that shifts to a state (for example, see Patent Document 1).
JP 2004-142517 A

However, the conventional technology that performs stop determination based on the passage of time after the vehicle speed becomes undetectable tends to cause a difference between the actual vehicle stop timing and the stop determination timing, and the vehicle still stops. In spite of this, there is a possibility that the electric parking brake operates, or conversely, the vehicle moves due to a time lag from when the vehicle stops until the electric parking brake operates. Such a time lag may occur, for example, for a maximum of about 2 seconds, and improvement is desired.
An object of the present invention is to provide a vehicle stop determination method, an electric parking brake control method, a vehicle stop determination device, and an electric parking brake device that accurately determine the stop of the vehicle.

The present invention solves the above-described problems by the following means.
According to a first aspect of the present invention, in a vehicle stop determination method for determining stop of a vehicle, a vehicle speed detection step for detecting that the speed of the vehicle is equal to or lower than a detection limit speed of a vehicle speed sensor, and an output of the vehicle speed sensor An inclination acceleration estimating step for obtaining an estimated inclination acceleration due to a road surface inclination based on an output of an acceleration sensor for detecting a vehicle speed reduction rate and an acceleration in the longitudinal direction of the vehicle, and an acceleration sensor of the acceleration sensor after the vehicle speed detecting step A first stop determination step for determining stop of the vehicle according to an output change, and a first stop determination step for determining stop of the vehicle by comparing the output of the acceleration sensor and the estimated inclination acceleration after the vehicle speed detection step. 2 stop determination step and the first stop determination based on the vehicle speed decrease rate before the output of the vehicle speed sensor becomes equal to or lower than the detection limit output. Step, a vehicle stop determination method characterized by comprising a deceleration state determining step of selecting one of the execution of the second stop determination step.
According to a second aspect of the present invention, in the vehicle stop determination method according to the first aspect, the first stop determination step is detected based on a change from the deceleration side to the acceleration side of the acceleration in the longitudinal direction of the vehicle. A vehicle stop determination method characterized by the following.
According to a third aspect of the present invention, in the vehicle stop determination method according to the first or second aspect , based on the deceleration of the vehicle before the vehicle speed becomes the detection limit speed and the detection limit speed, A stop estimation time calculating step for estimating a time from when the vehicle speed falls below the detection limit speed until the vehicle stops, and a time measurement step for measuring a time after the vehicle speed falls below the detection limit speed And a backup stop determination step for determining stop of the vehicle regardless of the stop determination step when the measured time is equal to or longer than a predetermined standby time set longer than the estimated stop time. This is a characteristic vehicle stop determination method.

According to a fourth aspect of the present invention, in the electric parking brake control method for switching between a braking state and a released state of the parking brake driven by the electric actuator, the vehicle stop determination according to any one of the first to third aspects. The electric parking brake control method is characterized in that the parking brake is shifted from the released state to the braking state in accordance with the stop determination obtained by the method.

According to a fifth aspect of the present invention, in a vehicle stop determination device for determining stop of a vehicle, a vehicle speed sensor that detects the speed of the vehicle, an acceleration sensor that detects acceleration in the longitudinal direction of the vehicle, and an output of the vehicle speed sensor. A slope acceleration estimating unit that obtains an estimated slope acceleration caused by a slope of the road surface based on a vehicle speed reduction rate and an output of the acceleration sensor; and an output of the acceleration sensor when the output of the vehicle speed sensor falls below a detection limit output. A first stop determination mode for determining stop of the vehicle according to an output change, and a second stop determination mode for determining stop of the vehicle by comparing the output of the acceleration sensor and the estimated inclination acceleration. And the first stop determination mode or the second stop determination mode based on the vehicle speed decrease rate before the output of the vehicle speed sensor becomes equal to or lower than the detection limit output. A vehicle stop determination apparatus characterized by comprising a stop determination unit that selects.
According to a sixth aspect of the present invention, in the vehicle stop determination device according to the fifth aspect, in the first stop determination mode, stop is determined based on a change from the deceleration side to the acceleration side of the output of the acceleration sensor. This is a vehicle stop determination device.
According to a seventh aspect of the present invention, in the vehicle stop determination device according to the fifth or sixth aspect, the stop determination unit is configured to detect the vehicle deceleration and the detection before the vehicle speed becomes equal to or lower than the detection limit speed. Based on a limit speed, a stop estimation time calculation unit that estimates a time from when the vehicle speed falls below the detection limit speed until the vehicle stops, and after the vehicle speed falls below the detection limit speed A time measuring unit for measuring the time of the first stop determination mode and the second stop determination mode when the measured time reaches a predetermined standby time set longer than the estimated stop time. A vehicle stop determination device comprising a backup stop determination unit that automatically determines stop regardless of whether or not .

The invention of claim 8 controls the electric actuator to change braking force of the parking brake, the electric parking brake control system for switching a release state and the braking state of the parking brake, of the claims 5 to claim 7 An electric parking brake control device comprising the vehicle stop determination device according to any one of claims 1 to 3, wherein the parking brake is shifted to a braking state in accordance with a stop determination in the vehicle stop determination device.

According to the present invention, the following effects can be obtained.
(1) When the vehicle is decelerating, the front suspension strokes to the compression side (contraction side) (nose dive). Since the behavior change in the direction occurs, the vehicle stoppage is determined based on such a behavior change in the pitching direction, so that the vehicle stoppage is accurately determined even at an extremely low speed below the detection limit speed of the vehicle speed sensor. be able to.
(2) The determination accuracy can be further improved by determining the stop of the vehicle using the estimated stop time calculated based on the deceleration of the vehicle in addition to the behavior change in the pitching direction of the vehicle.
(3) A noticeable nose dive occurs in the vehicle by determining whether the vehicle is stopped based on a comparison between the estimated inclination acceleration and the actual acceleration instead of a change in the behavior of the vehicle in the pitching direction according to the deceleration of the vehicle. Even during slow braking that is difficult to perform, it is possible to accurately determine whether the vehicle has stopped.
(4) It is necessary to add a new sensor if the vehicle has a longitudinal acceleration sensor by detecting the behavior of the vehicle in the pitching direction based on the change (inversion) of the longitudinal acceleration from the deceleration side to the acceleration side. Therefore, the apparatus configuration can be simplified.
(5) When the vehicle speed has been below the detection limit speed of the vehicle speed sensor for a predetermined waiting time, by determining stop regardless of other parameters, a failure or the like has occurred in a part of the device. Even if it exists, stop determination can be performed and fail-safe property improves.

  The present invention aims to provide a vehicle stop determination method and the like for accurately determining the stop of the vehicle. After the vehicle speed detected by the vehicle speed sensor becomes zero, the front and rear G detected by the G sensor from the deceleration side. Solved by determining stoppage of the vehicle in response to inversion to the acceleration side, and calculating the estimated slope G based on the G sensor output and the vehicle speed reduction rate, and comparing this with the G sensor output To do.

Embodiments of an electric parking brake device to which the present invention is applied will be described below. This electric parking brake device includes a vehicle stop determination device that executes the vehicle stop determination method according to the present invention.
FIG. 1 is a diagram showing a mechanical configuration of the electric parking brake device of the present embodiment. FIG. 2 is a block diagram showing a circuit configuration of the electric parking brake device.
The electric parking brake device includes a parking brake 10, an actuator unit 20, a battery 30, a controller 40, an operation switch 50, and a vehicle side unit 60.

  The parking brake 10 is a braking device that prevents the vehicle from moving when the vehicle is parked or the like, for example, by braking the wheels of the vehicle. The parking brake 10 is provided on each of the wheel hub portions of the left and right rear wheels of the vehicle. The parking brake 10 includes a brake drum (not shown) disposed on the inner diameter side of a rotor of a disc brake used as a foot brake (main brake) and a brake shoe (not shown) that pressurizes and contacts the inner diameter side of the brake drum during braking. It is a so-called drum-in-disc type.

The actuator unit 20 drives the shoe of the parking brake 10 and makes a transition between a braking state in which the parking brake 10 generates a braking force and a released state in which the braking force is not substantially generated. The actuator unit 20 includes a parking brake cable 21 and is fixed to, for example, a floor panel portion of the vehicle.
For example, the actuator unit 20 reduces the rotational force of a direct current (DC) motor by a reduction gear train, rotates a lead screw, and pulls or relaxes the parking brake cable 21 by an equalizer screwed to the lead screw. is there.

The parking brake cables 21 are provided corresponding to the left and right parking brakes 10, respectively, and have flexibility so as to be deformed according to a stroke of a rear suspension (not shown). The parking brake cable 21 brings the parking brake 10 into a braking state by being pulled, and releases the parking brake 10 by being relaxed.
Here, the actuator unit 20 has a function of adjusting the braking force of the parking brake 10 in the braking state by adjusting the traction force applied to the parking brake cable 21. The adjustment of the traction force is performed by changing the stroke with which the actuator unit 20 pulls the parking brake cable 21. For this reason, the actuator unit 20 is provided with a stroke sensor (not shown) that detects this stroke.

The battery 30 is a secondary battery that is used as a main power source for a vehicle electrical system, and generates, for example, a DC 12V terminal voltage. The battery 30 includes a plus terminal 31 and a minus terminal 32.
The plus terminal 31 is connected to the controller 40 via wiring (harness). As shown in FIG. 2, the wiring for supplying power from the plus terminal 31 to the controller 40 is provided with an ignition wiring 31a and a constant connection wiring 31b. The ignition wiring 31a is inserted at its intermediate portion with an ignition relay I that is switched between conducting and shutting off in conjunction with the on / off of the ignition switch, and is energized when the engine that is the power source for driving the vehicle is turned on. The always-connected wiring 31b is always energized regardless of the operation of the ignition switch.
The minus terminal 32 is grounded with respect to the vehicle body.

The controller 40 is an electric parking brake control device that controls the actuator unit 20 and changes the braking force of the parking brake 10 by changing the traction force of the parking brake cable 21, and includes an ECU 41, a relay 42, and a G sensor 43. ing.
The ECU 41 determines whether or not the parking brake 10 needs to be braked in response to inputs from the operation switch 50 and the vehicle-side unit 60, and also performs a CPU that performs an increase / decrease control for increasing the braking force when stopping on an inclined road. I have. ECU41 is provided with the integrated controller 41a, the stop determination part 41b, and the inclination determination part 41c.
The integrated controller 41a comprehensively controls the stop determination unit 41b, the inclination determination unit 41c, and the like.
The stop determination unit 41b performs a vehicle stop determination process, which will be described later. The stop determination unit 41b also serves as a stop time calculation unit that calculates an estimated stop time used in this process, and an inclination acceleration estimation unit that calculates a slope estimation G. It functions.
The inclination determination unit 41c processes the output of the G sensor 43 to perform a known inclination determination process for determining the inclination of the road surface on which the vehicle stops, and in the vehicle stop determination process, based on the output of the G sensor 43, A change in behavior in the pitching direction is detected.

The relay 42 supplies driving power to the actuator unit 20 in accordance with a control signal output from the ECU 41. The relay 42 shifts the parking brake 10 from the braking state to the released state, and brakes from the released state. In order to make the transition to the state, it has a function of reversing the polarity of the drive power and is in a neutral state in which the connection with the actuator unit 20 is interrupted except when the actuator unit 20 is driven.
The G sensor 43 includes an acceleration sensor that detects an actual acceleration (actual acceleration) in the front-rear direction of the vehicle, and inputs the output to the ECU 41. The G sensor 43 functions as a behavior detection unit that detects a behavior change in the pitching direction in cooperation with the inclination determination unit 41c of the ECU 41 in the vehicle stop determination. In the present specification, the polarity of acceleration in the longitudinal direction of the vehicle will be described below with the deceleration side being positive and the acceleration side being negative.

  The operation switch 50 is an operation unit for a user such as a driver to input a manual selection operation of the parking brake 10 and a release state of the parking brake 10 and a retraction operation, and is mounted on an instrument panel (not shown) of the vehicle, for example. Equipped with a push button switch. The operation switch 50 transmits the input to the controller 40, and the controller 40 supplies driving power to the actuator unit 20 in response to this to drive the parking brake 10.

The vehicle-side unit 60 includes, for example, an engine control unit (ECU) that controls the engine of the vehicle, a transmission control unit (TCU) that controls a transmission (transmission), a VDC control unit that performs VDC control including ABS control, A vehicle integration unit that comprehensively controls other electrical components is provided, and communicates with the controller 40 via a CAN communication system that is a type of in-vehicle LAN, and includes a vehicle speed sensor 61.
The vehicle speed sensor 61 is provided, for example, in a wheel hub portion, and is used for detecting a vehicle traveling speed (body speed) by outputting a vehicle speed pulse signal corresponding to the rotational speed of a tone wheel that rotates with the wheels. .
The vehicle side unit 60 and the vehicle speed sensor 61 constitute a vehicle stop determination device to which the present invention is applied in cooperation with the controller 40.

The vehicle side unit 60 sequentially provides the controller 40 with information such as engine speed, accelerator opening, transmission shift position, foot brake operation status, vehicle speed (vehicle speed), and the like. In the automatic operation mode, the controller 40 shifts the parking brake 10 from the braking state to the released state when it is determined that the vehicle shifts from the stopped state to the traveling state based on these inputs.
On the other hand, when the controller 40 determines that the vehicle has shifted from the running state to the stopped state (stop determination), the controller 40 determines that the parking brake 10 needs to be braked and supplies driving power to the actuator unit 20 to supply the parking brake 10. Is shifted from the release state to the braking state.
This stop determination will be described in detail below.

Next, a stop determination method in the electric parking brake device of this embodiment will be described. The electric parking brake device according to the present embodiment uses a stop determination method in which the logic is different between normal deceleration (at high G) and slow deceleration (at low G) where deceleration is smaller than that during normal deceleration. .
When the ECU 41 of the controller 40 detects the start of deceleration of the vehicle according to the decrease in the vehicle speed detected by the vehicle-side unit 60 using the vehicle speed sensor 61, the ECU 41 sets the rate of decrease (deceleration) of the vehicle speed to a predetermined threshold It is determined whether the deceleration is a comparatively large normal deceleration or a slow deceleration whose deceleration is smaller than the normal deceleration (deceleration state determination step). When the normal deceleration is detected, the electric parking brake device determines the stop of the vehicle by the high G stop determination method. When the slow deceleration is detected, the electric parking brake device detects the vehicle by the low G stop determination method. Determine whether to stop.
Hereinafter, each stop determination method will be described.

<< Stop determination method for high G time >>
FIGS. 3 and 4 are a first partial diagram (main routine) and a second partial diagram (stop determination logic subroutine) of the flowchart showing the high G time vehicle stop determination method in the electric parking brake device of this embodiment.
Hereinafter, the steps will be described step by step.
<Main routine>
<Step S01: Reception of vehicle speed Vso>
The ECU 41 of the controller 40 receives the vehicle body speed (vehicle speed) Vso that is the vehicle traveling speed detected by the vehicle-side unit 60 using the vehicle speed sensor 61, and proceeds to step S02.
<Step S02: G sensor output stock processing>
The ECU 41 performs stock processing of the output SG (sen_g) of the G sensor 43, updates the previous G sensor output SGold with the current G sensor output SG, and proceeds to step S03.
<Step S03: G sensor output SG capture>
The ECU 41 newly takes in the output SG from the G sensor 43, and proceeds to step S04. Here, the sign of the output SG of the G sensor 43 is set so that the deceleration side is positive and the acceleration side is negative.

<Step S04: Vehicle Speed Vso Determination (Vehicle Speed Detection Step)>
The ECU 41 compares the current vehicle speed Vso with the Vso at the start of processing (start Vso). If the current vehicle speed Vso is smaller than the start Vso and greater than 0, the process proceeds to step S06. If the current vehicle body speed Vso is 0, the process proceeds to step S14, and the processing of the subsequent stop determination logic subroutine (FIG. 4) is started. In other cases, the process proceeds to step S05.
<Step S05: Calculation Result Initialization>
The ECU 41 erases all internal calculation results including the above-described steps S01 to S04, resets parameters such as SGold, V [0,... N], Fst, Fsg, Gr, Grf, T, and the like. Returning to S01, the subsequent processing is repeated.
<Step S06: Travel determination output>
The ECU 41 outputs a traveling determination indicating that it is determined that the vehicle is traveling, and proceeds to step S07.

<Step S07: Stop Determination Flag Fst Determination Based on Stop Determination Time>
The ECU 41 determines whether or not a stop determination flag Fst, which is a flag indicating whether or not a stop determination condition is satisfied based on a stop determination time (stop time) ST described later, is 0. If not, the ECU 41 proceeds to step S08. If it is 0, the process proceeds to step S09.
<Step S08: Stop determination flag Fst, stop estimated time ST initialization>
The ECU 41 sets the stop determination flag Fst and the stop estimated time ST to 0, and proceeds to step S09.

<Step S09: Stop Determination Flag Fsg Determination by G>
The ECU 41 determines whether or not the stop determination flag Fsg, which is a flag indicating whether or not the stop determination condition based on the G sensor output SG is satisfied, is 0. If not, the ECU 41 proceeds to step S10. Proceed to S11.
<Step S10: Initialization of Stop Determination Flag Fsg by G>
The ECU 41 sets the stop G flag Fsg to 0, and proceeds to step S11.

<Step S11: Vehicle speed V stock processing>
The ECU 41 updates the accumulated time-series vehicle body speed data V [N] (N: integer) with V [N−1], respectively, and sets the current vehicle body speed Vso to V [0]. And proceed to step S12.

<Step S12: Reference G (Gr) Calculation>
The ECU 41 calculates a reference G (Gr), which is a reduction rate of the vehicle speed obtained by calculation based on the output of the vehicle speed sensor 61, as shown in Equation 1, and proceeds to step S13.

Gr (m / s ² )
= (V [N] (km / h) -V [0] (km / h)) / (T × N) × 1000/3600
... (Formula 1)
T: reception interval of vehicle speed Vso (s)
<Step S13: LPF Processing of Reference G>
The ECU 41 performs a predetermined low-pass filter (LPF) process on the reference G (Gr) calculated in step S12, generates a post-LPF reference G (Grf), returns to step S01, and the subsequent main routine Repeat the process.

<Stop judgment logic subroutine>
<Step S14: Stop estimated time ST determination>
The ECU 41 determines whether or not the stop determination time ST is 0. If the stop determination time ST is 0, the ECU 41 proceeds to step S15. If not, the ECU 41 proceeds to step S21.
<Step S15: Post-LPF Reference G (Grf) Determination>
The ECU 41 determines whether or not the reference G (Grf) after LPF obtained in step S13 is 0. If it is 0, the ECU 41 proceeds to step S16, and if it is not 0, the process proceeds to step S17.
<Step S16: Error output>
The ECU 41 generates a predetermined error signal on the assumption that an error has occurred in the stop determination process, and shifts to the backup mode.

<Step S17: Calculation of estimated stop time ST>
The ECU 41 calculates the estimated stop time ST based on the time history of the vehicle speed V [N], and proceeds to step S18.
FIG. 5 is a graph showing an example of the time history of the vehicle speed V detected based on the output of the vehicle speed sensor and the output SG of the G sensor in the vehicle of this embodiment, and during normal braking. .

The vehicle speed sensor 61 cannot detect the vehicle speed at an extremely low speed such as 2 km / h (detection limit speed) or less in principle, and the indicated value is within a speed range of 0 to 2 km / h. For example, it is maintained at 0 km / h.
Therefore, as shown in FIG. 5, when the vehicle decelerates to stop the vehicle, the ECU 41 changes the vehicle speed change rate (deceleration) and the detection limit speed immediately before the vehicle speed reaches 2 km / h. Based on 2 km / h, the estimated stop time ST is calculated by linear approximation, for example. That is, the estimated stop time is an estimated time until the vehicle stops when it is assumed that the deceleration when the speed is detectable is maintained.
Specifically, the estimated stop time ST is calculated by the following equation 2.

ST (s) = V [0] (km / h) / Grf (m / s ² ) × 1000/3600
... (Formula 2)

<Step S18: Comparison of estimated stop time ST and maximum estimated stop time STL>
The ECU 41 compares the estimated stop time ST calculated in step S17 with a maximum estimated stop time (stop time limit) STL that is a preset upper limit value of the estimated stop time ST, and the estimated stop time ST is estimated to be the maximum stop. When it is longer than the time STL, the process proceeds to step S19, and when the estimated stop time ST is equal to or less than the maximum estimated stop time STL, the process proceeds to step S20.
<Step S19: Change the estimated stop time ST to the maximum estimated stop time STL>
The ECU 41 sets the above-described maximum stop estimated time STL as a new estimated stop time ST instead of the estimated stop time ST calculated in step S17, and proceeds to step S20.

<Step S20: Stop determination timer start>
The ECU 41 starts timing by the stop determination timer and proceeds to step S21.
The stop determination timer is used to estimate the stop of the vehicle according to the elapsed time after the vehicle speed becomes equal to or lower than the detection limit speed and the vehicle speed cannot be detected by the vehicle speed sensor.

<Step S21: Timer value determination>
The ECU 41 compares the timer value T of the stop determination timer started in step S20 with the estimated stop time ST set in each step from steps S17 to S19 and a preset stop control time SCT. Here, the stop control time SCT is a standby time in which the stop determination is automatically performed when the vehicle body speed Vso is 0 for a longer time than this.
If the timer value T is equal to or greater than the stop control time SCT, the process proceeds to step S26 (backup stop determination). If the timer value T is less than the stop control time SCT and equal to or greater than the estimated stop time ST, the process proceeds to step S22. In this case, the process proceeds to step S23.
<Step S22: Stop determination flag Fst set based on estimated stop time>
The ECU 41 sets a stop determination flag Fst, which is a flag indicating that the stop determination condition based on the estimated stop time ST is satisfied, to 1, and proceeds to step S23.

<Step S23: G sensor output SG inversion determination>
The ECU 41 determines whether or not the product of the current G sensor output SG and the previous G sensor output SGold stocked in step S02 is 0 or less. If the product is 0 or less, the ECU 41 is based on the G sensor output. If the stop determination condition is satisfied, the process proceeds to step S24. If the stop determination condition is greater than 0, the process proceeds to step S25 assuming that the condition is not yet satisfied.
Here, when the vehicle stops, the front suspension strokes to the bounce (contraction) side due to the inertial force during deceleration, and the energy is accumulated from this state (nose dive state). Returning (extending) by the repulsive force causes a change in behavior in the pitching direction in which the front portion of the vehicle is lifted upward. At this time, as shown in FIG. 5, the acceleration in the longitudinal direction of the vehicle detected by the G sensor 43 is reversed from the deceleration side to the acceleration side, and then reversed again to the deceleration side, and finally the behavior converges. 0.
As described above, by monitoring the product of the G sensor output SG and the previous G sensor output SGold, such a behavior change in the pitching direction when the vehicle is stopped can be detected.
<Step S24: Stop determination flag Fsg set by G sensor output>
The ECU 41 sets the stop determination flag Fsg, which is a flag indicating that the stop determination condition based on the G sensor output SG is satisfied, to 1, and proceeds to step S25.

<Step S25: Stop Determination Flag Fst × Fsg Determination>
The ECU 41 obtains the product of the stop determination flag Fst based on the estimated stop time ST and the stop determination flag Fsg based on the G sensor output SG, and when this product is 1 (stop determination based on the estimated stop time and stop determination based on the G sensor output) If both are established), the process proceeds to step S26. Otherwise, the process returns to the main routine, and the subsequent processing is repeated.
<Step S26: Stop determination output>
The ECU 41 outputs a stop determination and ends the series of processes. When the stop determination is output, the controller 40 energizes the actuator unit 20 to shift the parking brake 10 to the braking state (hill hold). As a result, even if the driver releases his / her foot from the brake pedal immediately after the vehicle stops, it is possible to prevent the vehicle from starting to move due to the slope of the slope.

<< Low G stop determination method >>
FIGS. 6 and 7 are a first partial diagram (main routine) and a second partial diagram (stop determination logic subroutine) of the flowchart showing the low G vehicle stop determination method in the electric parking brake device of the present embodiment.
Hereinafter, description of the same parts as the above-described high G stop determination method will be omitted, and differences will mainly be described.

<Main routine>
<Step S101 to Step S102>
In each step from step S101 to step S102, substantially the same processing as in each step from step S01 to step S02 described above is performed, and after step S102 ends, the process proceeds to step S103.

<Step S103: Judgment of vehicle body speed Vso (vehicle speed detection step)>
The ECU 41 compares the current vehicle speed Vso with the Vso at the start of processing (start Vso). If the current vehicle speed Vso is smaller than the start Vso and greater than 0, the ECU 41 proceeds to step S104. If the current vehicle speed Vso is 0, the process proceeds to step S119, and the processing of the subsequent stop determination logic subroutine (FIG. 7) is started. In other cases, the process proceeds to step S112.

<Step S104 to Step S111>
In each step from step S104 to step S111, substantially the same processing as in each step from step S06 to step S13 described above is performed, and after step S111 ends, the process proceeds to step S113.

<Step S112: Initialization of calculation result>
The ECU 41 erases all internal calculation results including the above-described steps S01 to S04, and sets parameters such as SGold, V [0,... N], Fst, Fsg, Gr, Grf, Gc, Gcave, T, etc. The process is reset, the process returns to step S101, and the subsequent main routine processing is repeated.

<Step S113: Reference G determination>
The ECU 41 determines whether or not the reference G (Gr) obtained in step S110 is greater than 0. If it is greater than 0, the ECU 41 proceeds to step S114. If it is less than or equal to 0, the ECU 41 returns to step S101. Repeat the process. (return)
<Step S114: Gradient Estimation G Calculation>
The ECU 41 calculates an inclination estimate G (Gc) that is an estimated value of acceleration that is predicted to act on the vehicle due to the inclination of the road surface when the vehicle stops on the currently running road surface according to the following Equation 3. And proceeds to step S115.

Gradient estimate G (Gc) = LPF reference G (Grf) −G sensor output (SG) (Equation 3)

<Step S115: Average Gradient Estimation G Determination>
The ECU 41 determines whether or not the average gradient estimation G (Gcave), which is the average value of the gradient estimation G (Gc) described above, is 0. If it is not 0, the ECU 41 proceeds to step S116 and is 0. In this case, the process proceeds to step S117.
<Step S116: Gradient Estimation G Average Processing>
The ECU 41 calculates the average value by adding the previous average gradient estimate G (Gcave) and the gradient estimate G (Gc) calculated in step S114 immediately before, and dividing the result by 2. The average value Is updated to be a new average gradient estimation G (Gcave), and the process proceeds to step S118.
<Step S117: Average Gradient Estimate G Setting>
The ECU 41 sets the gradient estimation G (Gc) calculated in step S114 immediately before as the average gradient estimation G (Gcave), and proceeds to step S118.
<Step S118: Average Gradient Estimated G Output>
The ECU 41 outputs the average gradient estimation G (Gcave) set in each step from step S115 to step S117, returns to step S101, and repeats the subsequent processing. (return)

<Stop judgment logic subroutine>
<Step S119 to Step S127>
In each step from step S119 to step S127, substantially the same processing as in each step from step S14 to step S22 described above is performed, and after step S127 ends, the process proceeds to step S128.

<Step S128: G sensor output, average inclination estimation G comparison>
The ECU 41 compares the G sensor output SG with the average gradient estimation G (Gcave), and when the G sensor output SG is equal to or less than the average gradient estimation G (Gcave), the ECU 41 determines the stop based on the G sensor output SG. The process proceeds to step S129 assuming that the condition is satisfied, and otherwise proceeds to step S130 assuming that the condition has not been satisfied.

FIG. 8 is a graph showing another example of the time history of the vehicle speed V detected based on the output of the vehicle speed sensor and the output SG of the G sensor in the vehicle of the present embodiment, and the state at the time of slow braking. It is.
FIG. 8 shows a history when the vehicle stops with gentle braking while traveling downhill. In such a state, no significant nose dive occurs in the vehicle. The fluctuation of the front and rear G due to the behavior change in the pitching direction is small. Further, since the acceleration in the deceleration direction caused by the downhill gradient is always acting on the vehicle, in the example shown in FIG. 8, the G sensor output SG is always decelerated from during deceleration until after the vehicle stops. The G sensor output SG is not reversed as used for the stop determination in the high G stop determination method.
Therefore, in the low-G stop determination method, the average inclination estimation G (Gcave), which is an estimated value of acceleration caused by the road surface inclination, is used as a threshold value, and this is compared with the G sensor output SG. It is used as an element for determining whether to stop the vehicle.

<Step S129 to Step S131>
In each step from step S129 to step S131, substantially the same processing as in each step from step S24 to step S26 described above is performed, and a series of processing ends.

As described above, according to this embodiment, the following effects can be obtained.
(1) During normal deceleration with a relatively large deceleration G, a change in behavior in the pitching direction from the nose dive state to the normal state, which is generated by the repulsive force of the front suspension, is detected, and the stop of the vehicle is determined accordingly. Thus, it is possible to accurately determine whether the vehicle has stopped even in an extremely low speed region that is equal to or lower than the detection limit speed of the vehicle speed sensor.
As a result, the electric parking brake can be shifted from the released state to the braking state at an appropriate timing. For example, the vehicle is braked before the vehicle is completely stopped to generate a deceleration G that is not intended by the occupant, or the vehicle is stopped. Thereafter, the vehicle can be prevented from moving due to a time lag until the parking brake is activated.
(2) The determination accuracy can be further improved by determining the stop of the vehicle using the estimated stop time calculated based on the deceleration of the vehicle in addition to the behavior change in the pitching direction of the vehicle.
(3) During slow deceleration with a relatively small deceleration G, an inclination estimation G is obtained from the difference between the reference G calculated based on the output of the vehicle speed sensor and the G sensor output, and the G sensor output becomes smaller than the average value. In this case, it is difficult to detect the reversal of the front and rear G that occurs due to the behavior change in the pitching direction without causing a noticeable nose dive in the vehicle. However, the stop of the vehicle can be accurately determined.
(4) By detecting the behavior of the vehicle in the pitching direction based on the change (reversal) of the longitudinal acceleration from the deceleration side to the acceleration side, for example, the G sensor used for determining the inclination of the electric parking brake is used in the stop determination. It can also be used for behavior detection, and the apparatus configuration can be simplified.
(5) The stop control time SCT is set as a predetermined standby time, and after the output of the vehicle speed sensor 61 reaches 0 km / h, the stop determination is performed regardless of other parameters when this has elapsed. Even if a part of the apparatus such as the sensor 43 is broken, the stop determination can be performed, and the fail-safe property is improved.

(Modification)
The present invention is not limited to the embodiments described above, and various modifications and changes are possible, and these are also within the technical scope of the present invention.
(1) The embodiment relates to, for example, stop determination of the electric parking brake device. However, the vehicle stop determination method and the vehicle stop determination device of the present invention are not limited to this, and it is required to determine stop of the vehicle. The present invention can be applied to other uses, and is particularly suitable for switching between operation and non-operation using a stop as a trigger. For example, the present invention can be applied to stop determination in traffic jam tracking and stop determination to determine whether or not idle stop is possible.
(2) In the embodiment, the behavior change in the pitching direction of the vehicle is detected based on, for example, the reversal of the front and rear G from the deceleration side to the acceleration side. In the case of a vehicle equipped with a stroke sensor that performs the detection, detection may be performed based on the suspension stroke. Moreover, when detecting using an acceleration sensor, you may detect not only using the front-back G but using the acceleration of other directions, such as the up-and-down G, for example.
(3) The configuration of the electric parking brake device is not limited to that of the embodiment, and can be changed as appropriate.
For example, the parking brake of the embodiment uses a drum arranged on the inner diameter side of a brake disc for a foot brake, but the parking brake may be of other types, for example, for a foot brake. The disc brake or drum brake and its friction material may be shared and integrated with the parking brake.
Further, the parking brake of the embodiment uses an electric actuator fixed on the body side and drives the parking brake via a parking brake cable. However, the present invention is not limited to this, and for example, the electric actuator is a wheel. The present invention can also be applied to a so-called built-in type electric parking brake provided on the hub side and integrated with the parking brake.
(4) In the embodiment, the selection of the stop determination method for high G time and the stop determination method for low G time is performed based on the rate of decrease in the vehicle speed output from the vehicle speed sensor. The selection may be made based on the deceleration G detected by the acceleration sensor.

It is a figure which shows the mechanical structure of the Example of the electric parking brake apparatus to which this invention is applied. It is a block diagram which shows the circuit structure of the electric parking brake apparatus of FIG. FIG. 2 is a first partial view of a flowchart showing a high G stop determination method in the electric parking brake device of FIG. 1. FIG. 6 is a second partial diagram of a flowchart showing a high G stop determination method in the electric parking brake device of FIG. 1. It is a graph which shows an example of the time history of the vehicle speed and G sensor output of the vehicle with which the electric parking brake of FIG. 1 is mounted. FIG. 3 is a first partial view of a flowchart showing a low G time stop determination method in the electric parking brake device of FIG. 1. FIG. 6 is a second partial diagram of a flowchart showing a low-G time stop determination method in the electric parking brake device of FIG. 1. It is a graph which shows the other example of the time history of the vehicle speed and G sensor output of the vehicle with which the electric parking brake of FIG. 1 is mounted | worn.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 Parking brake 20 Actuator unit 21 Parking brake cable 30 Battery 40 Controller 41 ECU
43 G sensor 50 Operation switch 60 Vehicle side unit 61 Vehicle speed sensor

Claims (8)

In the vehicle stop determination method for determining stop of the vehicle,
A vehicle speed detecting step for detecting that the speed of the vehicle is equal to or lower than a detection limit speed of the vehicle speed sensor;
Inclination acceleration estimation step for obtaining an estimated inclination acceleration due to the inclination of the road surface based on the vehicle speed reduction rate obtained from the output of the vehicle speed sensor and the output of the acceleration sensor for detecting the acceleration in the longitudinal direction of the vehicle;
A first stop determination step of determining stop of the vehicle according to an output change of the acceleration sensor after the vehicle speed detection step;
A second stop determination step for determining stop of the vehicle by comparing the output of the acceleration sensor and the estimated inclination acceleration after the vehicle speed detection step;
Deceleration state determination step for selecting execution of either the first stop determination step or the second stop determination step based on the vehicle speed decrease rate before the output of the vehicle speed sensor becomes equal to or less than the detection limit output; A vehicle stop determination method comprising: In the vehicle stop determination method according to claim 1,
The vehicle stop determination method, wherein the first stop determination step is detected based on a change in acceleration in a longitudinal direction of the vehicle from a deceleration side to an acceleration side. In the vehicle stop determination method according to claim 1 or 2,
Based on the vehicle deceleration before the vehicle speed reaches the detection limit speed and the detection limit speed, a stop for estimating the time until the vehicle stops after the vehicle speed falls below the detection limit speed An estimated time calculating step;
A time measuring step of measuring a time after the speed of the vehicle falls below the detection limit speed;
A backup stop determination step of determining stop of the vehicle regardless of the stop determination step when the measured time is equal to or longer than a predetermined standby time set longer than the estimated stop time. A vehicle stop determination method. In an electric parking brake control method for switching between a braking state and a releasing state of a parking brake driven by an electric actuator,
An electric parking brake, wherein the parking brake is shifted from a released state to a braking state in response to a stop determination obtained by the vehicle stop determination method according to any one of claims 1 to 3. Control method. In the vehicle stop determination device for determining the stop of the vehicle,
A vehicle speed sensor for detecting the speed of the vehicle;
An acceleration sensor for detecting acceleration in the longitudinal direction of the vehicle;
An inclination acceleration estimation unit for obtaining an estimated inclination acceleration due to a road surface inclination based on the vehicle speed decrease rate obtained from the output of the vehicle speed sensor and the output of the acceleration sensor;
A first stop determination mode for determining stop of the vehicle according to a change in the output of the acceleration sensor when the output of the vehicle speed sensor becomes equal to or less than a detection limit output; and the output of the acceleration sensor and the estimated inclination acceleration And a second stop determination mode for determining stop of the vehicle,
A stop determination unit that selects the first stop determination mode or the second stop determination mode based on the vehicle speed decrease rate before the output of the vehicle speed sensor becomes equal to or lower than a detection limit output. A vehicle stop determination device. In the vehicle stop determination device according to claim 5,
The first stop determination mode performs stop determination based on a change from the deceleration side to the acceleration side of the output of the acceleration sensor. In the vehicle stop determination device according to claim 5 or 6,
The stop determination unit is configured to stop the vehicle after the vehicle speed falls below the detection limit speed based on the vehicle deceleration and the detection limit speed before the vehicle speed falls below the detection limit speed. An estimated stop time calculation unit that estimates the time until
A time measuring unit for measuring a time after the speed of the vehicle falls below the detection limit speed;
When the measured time reaches a predetermined standby time set longer than the estimated stop time , the stop is automatically determined regardless of the first stop determination mode and the second stop determination mode. A vehicle stop determination device comprising: a backup stop determination unit to perform. In the electric parking brake control device that controls the electric actuator that changes the braking force of the parking brake to switch between the braking state and the releasing state of the parking brake,
An electric parking system comprising the vehicle stop determination device according to any one of claims 5 to 7, wherein the parking brake is shifted to a braking state in accordance with a stop determination in the vehicle stop determination device. Brake control device.

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