JP2012240641A - Brake control device for vehicle - Google Patents

Abstract

PROBLEM TO BE SOLVED: To manage without generating excessive braking force, while preventing slipping-down of a vehicle by braking force by an EPB.SOLUTION: When the vehicle stops since a vehicle speed becomes 0, even if a G sensor value of a G sensor 21 is varied by pitching, target braking force is updated along a peak value of amplitude of the variation waveform. Thus, the target braking force set based on the G sensor value can be further approached to a value corresponding to a road surface pitch. Thus, while preventing slipping-down of the vehicle by the braking force by the EPB, generation of the excessive braking force can be avoided.

Description

  The present invention relates to a vehicle brake control device using an electric parking brake (hereinafter referred to as EPB (Electric parking brake)).

  Conventionally, when a vehicle stops on a slope, a braking force corresponding to a road surface gradient is generated using EPB to prevent the vehicle from sliding down. The road surface gradient can be detected based on a gravitational acceleration component included in an output value (hereinafter referred to as G sensor value) of a longitudinal acceleration sensor (hereinafter referred to as G sensor). For this reason, the road surface gradient at the time of stopping is calculated from the detection signal of the G sensor at the time of stopping, and the braking force necessary for maintaining the stop (hereinafter referred to as the braking force required for stopping) according to the road surface gradient is used as the target braking force by the EPB. Is generated. Since the braking force generated by the EPB is determined by the current value of the current (hereinafter referred to as “motor current”) flowing through the EPB motor, the target current value corresponding to the target braking force is calculated, and the motor current is the target current value. By stopping the motor drive when reaching the maximum, a braking force according to the road surface gradient is generated.

  At this time, the road surface gradient is calculated from the G sensor value, but as shown in the timing chart showing the change of each value before and after the stop shown in FIG. 16, the G sensor value is in the process until the stop. fluctuate. Due to this variation, if the target braking force is calculated at a timing when the G sensor value is small (point A in the figure), the target braking force may be calculated at a value lower than the required braking force for stopping. Thus, when the target braking force is set to a value lower than the braking force required for stopping, the EPB operation stops when the braking force generated by the EPB (hereinafter referred to as output braking force) reaches the target braking force. Therefore, there is a concern that the output braking force may not be sufficient to stop the vehicle and the vehicle may slide down.

  For this reason, in Patent Document 1, the dynamic estimated road surface inclination estimated based on the traveling state during the traveling of the vehicle and the static estimated road surface inclination estimated based on the acceleration acting on the vehicle after stopping. After determining that the pitching caused by stopping of the vehicle has converged, the output braking force by the EPB is controlled based on the result of comparing the static estimated road surface inclination and the dynamic estimated road surface inclination. It has been proposed to do. That is, when the static estimated road slope is greater than the dynamic estimated road slope after the stop determination, the output braking force by the EPB is controlled to the target braking force set based on the static estimated road slope, and the pitching Therefore, it is possible to secure the necessary braking force to stop the vehicle without slipping down in the convergence state.

JP 2008-87698 A

  As shown in the timing chart showing the change of each value before and after the stop shown in FIG. 17, in the target braking force setting method of Patent Document 1, dynamic estimation of the target braking force based on acceleration before pitching convergence, Based on the static estimation of the target braking force based on the acceleration after the convergence of pitching, the higher one is set as the target braking force.

  However, if the driver activates the EPB immediately after the vehicle stops, the EPB operation starts before the G sensor value converges, so the G sensor value converges and the target braking force is statically estimated. In some cases, the output braking force of the EPB reaches the target braking force based on dynamic estimation. In this case, if the target braking force based on dynamic estimation is a value that does not satisfy the stopping required braking force, the output braking force by the EPB does not satisfy the stopping required braking force, and the vehicle may slip down. . In such a case, it is necessary to set the target braking force again after the vehicle stops, and the target braking force based on static estimation is set to a value that is equal to or greater than the required braking force for stopping. The target braking force based on static estimation is set again to compensate for vehicle slippage due to insufficient braking at the point (point B1 before point B in the figure). For this reason, when the output braking force of the EPB reaches the target braking force based on the static estimation for the second time (point B2 in the figure), the increased braking force is applied and vehicle vibration occurs.

  On the other hand, by monitoring the G sensor value at the time of stopping and calculating the target braking force based on the largest value of the G sensor value, the target braking force is set to a value larger than the braking required braking force. It is possible to do so. Specifically, as shown in the timing chart showing the change of each value before and after the stop shown in FIG. 18, the braking force corresponding to the maximum value of the G sensor value after the vehicle speed becomes zero is always the target. By using the braking force, the target braking force can be made larger than the required braking force.

  However, as the pitching converges, the braking force corresponding to the G sensor value decreases, and the target braking force set based on the maximum value of the G sensor value deviates from the actual braking required braking force, as indicated by point C in the figure. In addition, the target braking force may greatly exceed the stopping required braking force. In this case, the braking force by the EPB is excessively output. For this reason, when controlling the output braking force of the EPB by controlling the current supplied to the actuator provided in the EPB, the durable load of the actuator becomes high and wasteful energy is consumed.

  An object of the present invention is to provide a vehicular brake control device that does not generate excessive braking force while preventing the vehicle from sliding down by the braking force generated by EPB.

  In order to achieve the above object, according to the first aspect of the present invention, the braking force by the EPB (2) is generated by driving the electric motor (10), and the termination condition is that the braking force reaches the target braking force. The lock control means (150) for performing the lock control for stopping the drive of the electric motor (10) and maintaining the brake force to be locked, and the peak of the vibration of the output waveform of the acceleration sensor value generated when the vehicle is stopped And a lock control target calculation means (140) for setting a target braking force based on the effective peak value and calculating a target braking force based on the effective peak value.

  Thus, when the vehicle stops, even if the acceleration sensor value of the acceleration sensor (21) fluctuates due to pitching, the target braking force is updated along the peak value of the amplitude of the output waveform. Thereby, the target braking force set based on the acceleration sensor value can be made closer to a value corresponding to the road surface gradient. For this reason, it is possible to prevent an excessive braking force from being generated while preventing the vehicle from sliding down by the braking force generated by the EPB (2).

  In the invention according to claim 2, the lock control target calculation means (140) sets the effective peak value from the peak value of the absolute value of the acceleration sensor value, and 1 out of the peak value of the absolute value of the acceleration sensor value. Set the first peak value as the first effective peak value, and compare the first peak value and the second peak value out of the absolute peak values of the acceleration sensor values. The effective peak value is updated to the peak value of the absolute value of the odd-numbered acceleration sensor value. If the second time is larger, the effective peak value is updated to the peak value of the absolute value of the even-numbered acceleration sensor value. It is characterized by that.

  The absolute value of the acceleration sensor value becomes a mountain-shaped waveform only when the acceleration sensor value increases during vibration because the acceleration sensor value becomes negative when the acceleration sensor value becomes negative. Rather, when it decreases, it becomes a mountain-shaped waveform. Therefore, by comparing the peak values of the absolute values of the first and second times, that is, adjacent acceleration sensor values, whichever of the absolute value peak values of the acceleration sensor values calculated in the odd and even times is effective. Whether it is a peak value can be determined.

  In the invention according to claim 3, when the number of times the peak value of the absolute value of the acceleration sensor value is calculated is the second or later, the lock control target calculating means (140) calculates the peak value of the absolute value of the acceleration sensor value. When the sign of the acceleration sensor value at the time of calculation is updated to the peak value of the absolute value of the odd-numbered acceleration sensor value, the acceleration sensor when the peak value of the absolute value of the first acceleration sensor value is calculated Acceleration sensor value when the absolute value peak value of the second acceleration sensor value is calculated when it coincides with the positive or negative sign of the value or when it is updated to the absolute value peak value of the even number of acceleration sensor values The peak value of the absolute value of the acceleration sensor value is calculated regardless of whether the peak value of the absolute value of the acceleration sensor value is calculated odd or even. It is characterized by updating the effective peak value to the value.

  As in the second aspect of the present invention, either the peak value of the absolute value of the acceleration sensor value calculated at the odd-numbered time or the even-numbered time can be updated as the effective peak value. When it is always a positive value or always a negative value, or when the amplitude of the G sensor output converges and always becomes a positive value or always a negative value after the second time, it is updated as an effective peak value every time. It will be. For this reason, when the sign of the acceleration sensor value when the peak value of the absolute value of the acceleration sensor value is calculated is updated to the peak value of the absolute value of the odd number of acceleration sensor values, the first acceleration sensor value When the peak value of the acceleration sensor value coincides with the sign of the acceleration sensor value when the absolute value is calculated, or when the peak value of the absolute value of the even-numbered acceleration sensor value is updated, the second acceleration sensor value The effective peak value is updated every time when it matches the sign of the acceleration sensor value when the peak value of the absolute value is calculated.

  In addition, the code | symbol in the bracket | parenthesis of each said means shows the correspondence with the specific means as described in embodiment mentioned later.

1 is a schematic diagram showing an overall outline of a brake system to which a vehicle brake control device according to a first embodiment of the present invention is applied. It is the flowchart which showed the detail of the parking brake control process. It is a flowchart of a lock control target calculation process. It is the flowchart which showed the detail of G sensor peak value calculation processing. It is the flowchart which showed the detail of G sensor peak temporary value calculation processing. It is the flowchart which showed the detail of the MAX peak value calculation process. It is the flowchart which showed the detail of the MIN peak value calculation process. (A) shows the relationship between the vibration waveform of the G sensor value and the peak value of the G sensor value (hereinafter referred to as the G sensor peak value), and (b) is used to calculate the G sensor peak value. It is the timing chart which showed the change of each value to do. It is the figure which showed the example of a waveform of G sensor value and its absolute value. It is the figure which showed the example of a waveform of G sensor value and its absolute value. It is the figure which showed the example of a waveform of G sensor value and its absolute value. It is the figure which showed the example of a waveform of G sensor value and its absolute value. It is the figure which showed the example of a waveform of G sensor value and its absolute value. It is the figure which showed the example of a waveform of G sensor value and its absolute value. It is the flowchart which showed the detail of lock control processing. It is a map which shows the relationship between W / C pressure corresponding to target braking force, and target motor current value rise amount TMIUP. It is the map which showed the relationship between M / C pressure and the subtraction value IDOWN. It is the flowchart which showed the detail of release control processing. It is the flowchart which showed the detail of lock release display processing. It is a timing chart when a parking brake control process is performed. It is a timing chart which showed change of each value before and after stopping. It is a timing chart which showed change of each value before and after stopping. It is a timing chart which showed change of each value before and after stopping.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. In the following embodiments, the same or equivalent parts are denoted by the same reference numerals in the drawings.

(First embodiment)
A first embodiment of the present invention will be described. In the present embodiment, a vehicle brake system in which a disc brake type EPB is applied to the rear wheel system will be described as an example. FIG. 1 is a schematic diagram showing an overall outline of a brake system to which a vehicle brake control device according to the present embodiment is applied. Hereinafter, a description will be given with reference to this figure.

  As shown in FIG. 1, the brake system includes a service brake 1 that generates a braking force based on the pedaling force of the driver and an EPB 2 that regulates the movement of the vehicle when parked.

  The service brake 1 uses a booster 4 to boost the pedaling force according to the driver's depression of the brake pedal 3, and then the brake fluid pressure corresponding to the boosted pedaling force is referred to as a master cylinder (hereinafter referred to as M / C). ) To generate a braking force by transmitting the brake hydraulic pressure to each W / C 6 provided in the brake mechanism of each wheel. Further, an actuator 7 for adjusting the brake fluid pressure is provided between the M / C 5 and the W / C 6 for adjusting the braking force generated by the service brake 1 and improving the safety of the vehicle. The structure can perform various controls (for example, anti-skid control).

  Various controls using the actuator 7 are executed by an ESC (Electronic Stability Control) -ECU 8. For example, by outputting a control current for controlling various control valves and pump driving motors provided in the actuator 7 from the ESC-ECU 8, the hydraulic circuit provided in the actuator 7 is controlled and transmitted to the W / C 6. W / C pressure is controlled. Since the structure of the actuator 7 is well known from the past, the details are omitted. However, the actuator 7 includes various control valves, a motor, and a reservoir, and controls the hydraulic circuit by controlling the various control valves. Thus, brake fluid pressure control is performed.

  On the other hand, the EPB 2 is controlled by an EPB control device (hereinafter referred to as “EPB-ECU”) 9, and the EPB-ECU 9 drives the motor 10 to control the brake mechanism to generate a braking force.

  The EPB-ECU 9 is composed of a well-known microcomputer having a CPU, ROM, RAM, I / O, and the like, and controls the rotation of the motor 10 according to a program stored in the ROM, etc. Perform parking brake control. The EPB-ECU 9 and the ESC-ECU 8 exchange information with each other through CAN communication that is an in-vehicle LAN, and the ESC-ECU 9 performs vehicle parking brake control, such as vehicle speed information handled by the ESC-ECU 8. Can be obtained.

  In addition, the EPB-ECU 9 detects, for example, a signal corresponding to an operation state of an operation switch (SW) 20 provided in an instrument panel (not shown) in a vehicle cabin, and a G sensor 21 that detects acceleration in the longitudinal direction of the vehicle. And the detection signal of the M / C pressure sensor 22 is input, and the motor 10 is driven according to the operation state of the operation SW 20, the G sensor value in the longitudinal direction of the vehicle, and the M / C pressure. Further, the EPB-ECU 9 outputs a signal indicating whether the vehicle is locked or released according to the driving state of the motor 10 to the lock / release display lamp 23 provided on the instrument panel.

  Specifically, the EPB-ECU 9 detects the current (motor current) flowing through the motor 10 on the upstream side or the downstream side of the motor 10, and the target motor current (target current value when the lock control is ended) ) For calculating the target motor current, determining whether or not the motor current has reached the target motor current, and controlling the motor 10 based on the operation state of the operation SW 20. Have. The EPB-ECU 9 controls to lock / release the EPB 2 by rotating the motor 10 forward or backward based on the state of the operation SW 20 or the motor current or stopping the rotation of the motor 10.

  The brake mechanism provided in each wheel has a mechanical structure that generates a braking force in the brake system of the present embodiment, and the brake mechanism of the front wheel system has a structure that generates a braking force by operating the service brake 1. However, the brake mechanism for the rear wheel system has a common structure for generating a braking force for both the operation of the service brake 1 and the operation of the EPB 2. The front-wheel brake mechanism is a brake mechanism that has been generally used in the past, in which a mechanism for generating a braking force based on the operation of the EPB 2 is eliminated from the rear-wheel brake mechanism. That is, the front-wheel brake mechanism generates a braking force for each wheel by pressing the brake pad 11 against the brake disc 12 as the driver operates the service brake 1. The rear wheel brake mechanism generates a braking force for each wheel by pressing the brake pad 11 against the brake disc 12 in accordance with the operation of the EPB 2 in addition to the operation of the service brake 1 by the driver.

  These brake mechanisms for generating a braking force by operating the front wheel system service brake 1 have been conventionally used, and the braking force corresponding to the operation of the rear wheel system service brake 1 and EPB 2 is used. The brake mechanism that generates the noise is also known, for example, in Japanese Patent Application Laid-Open No. 2010-58536. For this reason, description of a detailed structure is abbreviate | omitted here.

  Next, parking brake control executed by the EPB-ECU 9 in accordance with a program stored in the various functional units and a built-in ROM (not shown) using the brake system configured as described above will be described. FIG. 2 is a flowchart showing details of the parking brake control process.

  First, after general initialization processing such as a time measurement counter and flag reset is performed in step 100, the process proceeds to step 110 to determine whether or not the time t has elapsed. The time t here defines a control cycle. That is, the time t is determined by repeatedly performing the determination in this step until the time t after the initialization process is completed or the elapsed time since the previous positive determination was performed in this step. Parking brake control is executed every time elapses.

  In step 120, it is determined whether or not there is a lock request, for example, whether or not the operation SW 20 is turned on. The state in which the operation SW 20 is on means that the driver is operating the EPB 2 to lock it. Therefore, if an affirmative determination is made in this step, the routine proceeds to step 130, where it is determined whether or not the lock state is set based on whether or not the lock state flag FLOCK is on. Here, the lock state flag FLOCK is a flag that is turned on when the EPB 2 is operated to enter the locked state. When the lock state flag FLOCK is turned on, the operation of the EPB 2 has already been completed and is desired. The brake force is generated. Therefore, if a negative determination is made here, the process proceeds to a lock control target calculation process in step 140 to calculate a target braking force, and then proceeds to a lock control process in step 150. If an affirmative determination is made, lock control is already performed. Since the processing is completed, the process proceeds to step 160.

  On the other hand, if a negative determination is made in step 120, the process proceeds to step 170 to determine whether or not there is a release request, for example, whether the operation SW 20 has been switched from on to off. The state in which the operation SW 20 is switched from on to off means that the driver operates the EPB 2 to change from the locked state to the released state. Therefore, if an affirmative determination is made in this step, the routine proceeds to step 180, where it is determined whether or not the release state flag FREL is on. Here, the release state flag FREL is a flag that is turned on when the EPB 2 is operated and the release state, that is, the state in which the braking force by the EPB 2 is released, and the release state flag FREL is turned on. Sometimes the operation of EPB2 is already completed and the braking force is released. Accordingly, the process proceeds to the release control process of step 190 only when a negative determination is made here, and when the determination is affirmative, the process proceeds to step 160 because the release control process has already been completed.

  Then, after the lock control process and the release control process are completed, a lock / release display process in step 160 is performed. The parking brake control process is executed by such a process. Hereinafter, details of each part of the parking brake control process will be described.

  In the lock control target calculation process shown in step 140 of FIG. 2, the target braking force generated by the lock control process is calculated. This target braking force corresponds to the braking force required for stopping, and by generating the target braking force, it is possible to maintain the stopped state without sliding down. FIG. 3 is a flowchart of the lock control target calculation process.

  As shown in this figure, in step 200, it is determined whether or not all wheel speeds are 0 km / h, that is, whether or not the vehicle is stopped. Since the target braking force calculated in the lock control target calculation process is a braking force necessary to maintain the stop state while the vehicle is stopped, the subsequent process is executed only when the vehicle is stopped. If an affirmative determination is made here, the process proceeds to step 210 to determine whether or not there is an EPB control request. Regarding whether or not there is an EPB control request, whether or not the operation SW 20 is pressed by the driver, or whether or not a request for generating a target braking force is issued from a vehicle control application such as slope maintenance control. Based on the determination.

  If the determination in step 210 is affirmative, the process proceeds to step 220 where G sensor peak calculation processing is performed. In the G sensor peak calculation process, the G sensor peak value that fluctuates is calculated in the process in which the G sensor values in the front-rear direction detected by the G sensor 21 converge. As described above, when the driver activates the EPB 2 immediately after the vehicle stops, the operation of the EPB 2 is started before the vibration of the G sensor output converges, so that the vibration of the G sensor output converges. Therefore, the target braking force should be changed corresponding to the change of the G sensor value. For this reason, in the present embodiment, the G sensor peak value is calculated so that the target braking force can be changed corresponding to the changing G sensor value. Hereinafter, although G sensor peak calculation processing is performed based on each processing shown in Drawing 4-Drawing 7, the idea of G sensor peak calculation is explained first.

  FIG. 8A shows the relationship between the vibration waveform of the G sensor value and the G sensor peak value, and FIG. 8B shows the change of each value used to calculate the G sensor peak value. It is a timing chart.

  As shown in FIG. 8A, the G sensor value fluctuates immediately after the vehicle stops and then converges to a value corresponding to the road surface gradient. At this time, since the G sensor output gradually converges while vibrating, the G sensor value used for calculation of the target braking force is updated as indicated by the solid line in the figure as the G sensor peak value fluctuates. Thus, the target braking force can be changed in response to the change in the G sensor value. In the example shown in FIG. 8 (a), the G sensor value after convergence is a road surface gradient having a positive value. Therefore, if the G sensor peak value is obtained and updated sequentially, the target braking force can be calculated. It becomes an effective G sensor peak value (hereinafter referred to as an effective peak value) to be used. However, since the sign of the G sensor value is reversed between the uphill and the downhill, simply obtaining the G sensor peak value and updating it sequentially is suitable for use in calculating the target braking force. The effective peak value is not reached.

  For this reason, the absolute value of the G sensor value is used. However, when the absolute value of the G sensor value is used, the minimum value side of the G sensor value is also set to 0G as shown by the one-dot chain line in FIG. Therefore, a pseudo peak value (hereinafter referred to as a pseudo peak value) is generated, and the peak value is increased. Since this pseudo peak value is not an effective peak value appropriate for use in calculating the target braking force, it is not preferable to update the peak value used in calculating the target braking force when the pseudo peak value is used.

  For example, taking an example of the waveform of the G sensor value and its absolute value, the waveform is as shown in FIG. That is, when the first time is a pseudo peak value and the second time is an effective peak value as shown in FIG. 9A, the first time is the effective peak value and the second time is a pseudo peak value as shown in FIG. If the pseudo peak value is the first time and the effective peak value is the second time as shown in (c), but the pseudo peak value disappears due to the convergence of vibration, the first time is 2 as the effective peak value as shown in (d). When the pseudo peak value is lost due to the convergence of the vibration at the first time, but the G sensor value is all positive as shown in (e) and no pseudo peak value is generated, the G sensor is used as shown in (f). There are cases where all values are negative and pseudo peak values do not occur. For this reason, it is necessary to discriminate between the effective peak value and the pseudo peak value and update the peak value used for calculating the target braking force with only the effective peak value.

  Therefore, each value shown in FIG. 8B is obtained, and an effective peak value appropriate for use in calculating the target braking force is calculated using the values. Specifically, the MAX peak value and the MIN peak value of the absolute value of the G sensor value are calculated, and the G sensor peak temporary value, which is a temporary peak value, is calculated from the MAX peak value and the MIN peak value. An effective peak value appropriate for use in calculating the target braking force is calculated from the sensor peak provisional value.

  The MAX peak value is used to obtain a peak value that takes the maximum value of the absolute value of the G sensor value. The MIN peak value is used to obtain a peak value that takes the minimum value of the absolute value of the G sensor value. The G sensor peak provisional value is a value that temporarily determines the G sensor value that is finally used for calculating the target braking force.

  The MAX peak value basically increases as the absolute value of the G sensor value increases. Further, the MAX peak value is obtained on condition that the difference between the previously calculated MAX peak value and the absolute value of the G sensor value exceeds a certain value (for example, 10LSB) when the absolute value of the G sensor value decreases. Until the condition is satisfied, the previous MAX peak value is maintained. When this condition is satisfied, the absolute value of the G sensor value at that time is updated. For this reason, as shown in FIG. 8B, the MAX peak value increases in the same manner when the absolute value of the G sensor value increases, and decreases stepwise when the absolute value decreases.

  The MIN peak value basically decreases as the absolute value of the G sensor value decreases. The MIN peak value is set on condition that when the absolute value of the G sensor value increases, the difference between the previously calculated MIN peak value and the absolute value of the G sensor value is less than a certain value (for example, −10 LSB). Until this condition is satisfied, the previous MIN peak value is maintained, and when this condition is satisfied, the absolute value of the G sensor value at that time is updated. Therefore, as shown in FIG. 8B, the MIN peak value decreases in the same manner when the absolute value of the G sensor value is decreasing, and increases in a stepwise manner when it increases.

  The provisional G sensor peak value is a value that is provisionally determined as a G sensor value that is finally used for calculating the target braking force based on the MAX peak value or the MIN peak value. The provisional G sensor peak value increases with the increase of the MAX peak value, and during the period in which the MAX peak value is held, the peak waveform of the G sensor value in the period (waveform convex upward) ) Is held as a peak value. For this reason, as shown in FIG. 8B, the G sensor peak provisional value increases in the same way when the MAX peak value is increasing, and when the MAX peak value is held, the MAX peak value is Even if it decreases stepwise, the maximum MAX peak value at that time is maintained.

  Thus, when the G sensor peak provisional value is obtained, since the G sensor peak value includes a pseudo peak value, an appropriate effective peak is used as a peak value used for calculating the target braking force. The G sensor peak value is calculated by updating only to the value. This G sensor peak value has the waveform shown by the solid line in FIG. Hereinafter, the details of the G sensor peak value calculation processing will be specifically described with reference to FIGS.

  FIG. 4 is a flowchart showing details of the G sensor peak value calculation process. FIG. 5 is a flowchart showing details of the G sensor peak provisional value calculation process, and FIGS. 6 and 7 are flowcharts showing details of the MAX peak value calculation process and the MIN peak value calculation process.

  First, when G sensor peak value calculation processing is started, G sensor peak provisional value calculation processing is executed in step 300. In the G sensor peak provisional value calculation process, as shown in FIG. 5, after the MAX peak value calculation process is performed in step 400, the MIN peak value calculation process is performed in step 410.

  In the MAX peak value calculation process, as shown in FIG. 6, in step 500, the absolute value (| G sensor value |) of the G sensor value is calculated. In step 510, the MAX peak value Tmp is calculated. The MAX peak value Tmp is set to a larger one of the previous MAX peak value and the absolute value of the G sensor value. If the absolute value of the G sensor value is increasing, basically the absolute value of the G sensor value is larger than the previous MAX peak value by the increase of the G sensor value during one control cycle. Thus, the absolute value of the G sensor value is set to the MAX peak value Tmp. If the absolute value of the G sensor value is decreasing, basically the absolute value of the G sensor value is smaller than the previous MAX peak value by the decrease of the G sensor value in one control cycle. Therefore, the previous MAX peak value is set to the MAX peak value Tmp. However, as shown in step 550, which will be described later, since there is a timing when the MAX peak value is reset to 0, at that moment, the absolute value of the G sensor value becomes the MAX peak value Tmp.

  Thereafter, in step 520, it is determined whether or not the difference obtained by subtracting the absolute value of the G sensor value from the previous MAX peak value exceeds a certain value (for example, 10LSB). During the negative determination period, the process proceeds to step 530, and the MAX peak value Tmp calculated in step 510 is set as the MAX peak value. If an affirmative determination is made in step 520, the process proceeds to step 540 and the fact that the MAX peak value is being held is stored by setting a flag indicating that fact. In step 550, the MAX peak value is reset to 0, and the process ends.

  As described above, once the condition is satisfied in the determination in step 520, the MAX peak value is once reset to zero. Therefore, at the time of the next control cycle, the absolute value of the G sensor value at that time is immediately set to the MAX peak value at step 510. When the absolute value of the G sensor value is decreasing, the MAX peak value Tmp is set to the previous MAX peak value in step 510. Until the above condition is satisfied again, a negative determination is made in step 520, and the MAX peak Tmp is set to the current MAX peak value in step 530, so that the previous MAX peak value is held. As a result, as shown in FIG. 8B, the MAX peak value increases in the same manner when the absolute value of the G sensor value increases, and when it decreases, the MAX peak value decreases in a stepwise manner.

  In the MIN peak value calculation process, as shown in FIG. 7, in step 600, the absolute value of the G sensor value (| G sensor value |) is calculated. In step 610, the MIN peak value Tmp is calculated. The MIN peak value Tmp is set to the smaller one of the previous MIN peak value and the absolute value of the G sensor value. If the absolute value of the G sensor value is decreasing, basically the absolute value of the G sensor value is smaller than the previous MIN peak value by the decrease of the G sensor value in one control cycle. Therefore, the absolute value of the G sensor value is set to the MIN peak value Tmp. Further, if the absolute value of the G sensor value is increasing, the absolute value of the G sensor value is larger than the previous MIN peak value by the increase of the G sensor value in one control cycle. The previous MIN peak value is set to the MIN peak value Tmp. However, as shown in step 650, which will be described later, since there is a timing at which the MIN peak value is set to the maximum value in calculation, the absolute value of the G sensor value becomes the MIN peak value Tmp at that moment.

  Thereafter, in step 620, it is determined whether or not the difference obtained by subtracting the absolute value of the G sensor value from the previous MIN peak value is less than a certain value (for example, −10LSB). During the negative determination period, the process proceeds to step 630, where the MIN peak value Tmp calculated in step 610 is set as the MIN peak value. If an affirmative determination is made in step 620, the process proceeds to step 640 and the fact that the MAX peak value is not held is stored by resetting a flag indicating that the peak is being executed. Then, the process proceeds to step 650, the MIN peak value is set to the maximum value in the calculation, and the process ends. The calculation maximum value here is a maximum value assumed when the MIN peak value is calculated (for example, a default value corresponding to acceleration 10G). The maximum value in this calculation is always greater than or equal to the absolute value of the G sensor value.

  As described above, once the determination in step 620 satisfies the condition, the MIN peak value is set to the maximum value in the calculation. For this reason, the absolute value of the G sensor value at that time is immediately set to the MIN peak value in step 610 during the next control cycle. Further, while the absolute value of the G sensor value is increasing, in step 610, the MIN peak value Tmp is set to the previous MIN peak value. Until the above condition is satisfied again, a negative determination is made in step 620, and in step 630, the MIN peak Tmp is set to the current MIN peak value, so the previous MIN peak value is held. As a result, as shown in FIG. 8B, the MIN peak value has a waveform that decreases in the same manner when the absolute value of the G sensor value decreases and increases in a stepwise manner when it increases.

  In this way, when the MAX peak value calculation process and the MIN peak value calculation process are completed, it is determined in step 420 of FIG. 5 whether or not the MAX peak value is being held. Here, if the flag is set in step 540 described above, an affirmative determination is made, and if the flag is reset in step 640, a negative determination is made. If a negative determination is made, the process proceeds to step 430, where the MAX peak value obtained in the MAX peak value calculation process is set as a temporary G sensor peak value. If an affirmative determination is made, the process proceeds to step 440, where the previous MAX peak value is set to G. Set as a temporary sensor peak value.

  Thereafter, the process proceeds to step 450, and it is determined whether or not a condition for detecting the provisional G sensor peak value is satisfied. Although the G sensor peak provisional value is also set to the MAX peak value as in step 430, it is basically a provisional value of an effective peak value suitable for use in the calculation of the target braking force. When a value that can be used for the calculation of the target braking force is detected, the G sensor peak provisional value is detected. Here, it is assumed that a flag indicating the retention of the MAX peak value is set when the retention of the MAX peak value is started, and the temporary G sensor peak value is detected at this timing. Specifically, as shown in FIG. 8B, when a flag indicating that the MAX peak value is being held is set, the temporary G sensor peak value is detected only at the rising edge.

  Then, in step 450, the MAX peak value is being held and the previous value of the MAX peak value is not stored as a condition for detecting the temporary G sensor peak value, and this condition is satisfied. It is determined whether or not. If an affirmative determination is made here, the routine proceeds to step 460, where a flag indicating the presence of G sensor peak provisional value detection is set, and the count of the counter that measures the number of times of G sensor peak provisional value detection is increased, and the process is terminated. If a negative determination is made, the routine proceeds to step 470, where the G sensor peak provisional value is not detected, a flag indicating the presence of detection is reset, and the process is terminated. As described above, in the G sensor peak provisional value calculation process, the G sensor peak provisional value is calculated, and the presence / absence of G sensor peak provisional value detection and the number of times of G sensor peak provisional value detection are obtained.

  When the G sensor peak provisional value calculation process is completed in this way, the process proceeds to step 305 in FIG. 4 to determine whether or not the number of times the G sensor peak provisional value is detected is the second time. This determination is performed based on the count value of the counter that measures the G sensor peak provisional value detection count described in step 460 of FIG. If an affirmative determination is made here, it is determined in step 310 to 330 whether the first G sensor peak provisional value or the second G sensor peak provisional value is an effective peak value.

  First, in step 310, it is determined whether the second G sensor peak provisional value is larger than the previous (first) G sensor peak provisional value, so that the G sensor peak calculated in either the odd number or the even number is determined. It is determined whether the provisional value becomes an effective peak value. If an affirmative determination is made here, the process proceeds to step 315 to set a flag indicating that there is an update at the second and subsequent times, and then proceeds to step 320 to store the sign of the G sensor value at the time of G sensor peak provisional value calculation. . On the other hand, if a negative determination is made, the process proceeds to step 325 to set a flag indicating that there is an update in the second and subsequent odd times, and then proceeds to step 330 to store the sign of the G sensor value at the time of G sensor peak provisional calculation. .

  As shown in FIG. 8B, the absolute value of the G sensor value is a value obtained by inverting the positive value even when the G sensor value becomes a negative value. It does not become a mountain waveform only when the value increases, but also when it decreases. In this case, in order to distinguish the effective peak value and the pseudo peak value, the first and second times, that is, the adjacent G sensor peak provisional values are compared in magnitude, and the G sensor peak provisional values calculated in the odd number and even number times are compared. It is determined which of the values is the effective peak value. If the first time is larger than the second time, the effective peak value is updated every odd number of times. If the second time is larger than the first time, the effective peak value is updated every even number of times. In Steps 315 and 325, it is stored whether the update is performed evenly or oddly.

  However, if the G sensor value is always a positive value or always a negative value, or if fluctuations in the G sensor value have converged and have always become a positive value or a always negative value from the second time onward, When the absolute value of the sensor value is taken, the peak value of the adjacent mountain waveform is always a maximum value or always a minimum value. In this case, it is necessary to update the effective G sensor value every time it becomes a mountain-shaped waveform, and it is not sufficient to update the effective peak value only at odd or even times. It becomes.

  The case of updating each time such a mountain-shaped waveform can be determined based on the sign of the G sensor value. Specifically, the sign of the G sensor value when the G sensor peak provisional value used as the effective peak value is obtained is the first G sensor peak provisional if the odd number is determined to be the effective peak value. If the value coincides with the sign of the G sensor value when the value is obtained and the even number is determined to be an effective peak value, the sign of the G sensor value when the second provisional G sensor peak value is obtained Match. However, if the G sensor value is always a positive value or always a negative value, or if the vibration of the G sensor value converges and becomes always a positive value or always a negative value from the second time onward, the odd number The sign when the G sensor peak provisional value is obtained every time is the same for both the first and even times.

  For this reason, when the effective peak value is updated at an even number of times in step 320, the sign of the G sensor value at the time of the second G sensor peak provisional value calculation is stored, and the effective peak value is updated at an odd number of times. In the case of updating, the sign of the G sensor value at the previous (first) G sensor peak provisional value calculation is stored. Then, based on the stored contents in steps 315 to 330, it is determined whether or not the effective peak value is updated in step 335.

  In step 335, the following conditions are set as the effective peak value update conditions. First, when there is G sensor peak provisional value detection and the G sensor peak provisional value is detected for the first time, the update condition is unconditionally satisfied. When the temporary G sensor peak value is detected for the first time, the effective peak value is not yet set, so the temporary G sensor peak value at the first time is set as the first effective peak value. This condition is satisfied if the flag indicating that the G sensor peak provisional value is detected is set in step 460 of FIG. 5 and the count value of the counter for measuring the G sensor peak provisional value detection count is 1. become.

  Also, when the G sensor peak provisional value detection count is an odd number and is updated, and the G sensor peak provisional value detection count is an odd number (however, excluding the first), or the G sensor peak provisional value detection count is an even number. The update condition is also satisfied when the G sensor peak provisional value is detected an even number of times. It is determined whether or not these conditions are satisfied based on whether or not the contents stored in steps 315 to 330 described above. For example, when the G sensor peak provisional value detection count is updated at an odd number and the G sensor peak provisional value detection count is set to an odd number, the G sensor peak provisional value is detected as shown in FIG. The effective peak value is updated when the number of value detections is the third time, the fifth time, and the like.

  Furthermore, when the number of times the G sensor peak provisional value is detected is the second or later, and the sign of the stored G sensor value matches the sign of the G sensor value when the provisional G sensor peak value is detected. , To meet the update conditions. For example, it is effective when the G sensor value is always positive or always negative, or when the fluctuation of the G sensor value converges and always becomes positive or always negative after the second time. It is necessary to update the G sensor value every time it becomes a mountain-shaped waveform. Therefore, the effective peak value is updated even when this update condition is satisfied. For example, as shown in FIG. 8A, even if the number of times of G sensor peak provisional value detection is an odd number of times, when the vibration of the G sensor value converges, the G sensor peak provisional number is assumed after the sixth time. Each time a value is detected, the effective peak value is updated.

  If any of these various update conditions is satisfied, the process proceeds to step 340 to set a flag indicating that there is a peak value update, and then proceeds to step 345 to set the G sensor peak provisional value at that time as the effective peak value. To finish the process. If none of the update conditions is satisfied, the process proceeds to step 350, the peak value is not updated, the flag indicating that the peak value is updated is reset, and then the process proceeds to step 355, where the previous provisional G sensor peak value is set to the effective peak value. Set to, and the process ends.

  When the G sensor peak value calculation processing is completed in this way, the process proceeds to step 230 in FIG. 3 to determine whether or not the G sensor peak value has been updated. This determination is made based on whether the flag indicating that the peak value is updated is set or reset in steps 340 and 350 in FIG. If an affirmative determination is made in this step, the routine proceeds to step 240 where the target braking force is calculated. The target braking force is calculated by integrating the gravitational acceleration, the G sensor peak value (that is, the effective peak value), and the tire diameter with respect to the vehicle weight. Thereby, the lock control target calculation process is completed.

  In the lock control process shown in step 150 of FIG. 2, the EPB 2 is operated by rotating the motor 10, and the rotation of the motor 10 is stopped at a position where a desired braking force can be generated by the EPB 2, and this state is maintained. The process of doing. FIG. 10 is a flowchart showing details of the lock control process, and the lock control process will be described with reference to this figure.

  First, in step 700, it is determined whether or not the flag FIUPS is turned off when the current value starts to increase. The current value rise start flag FIUPS is a flag that is turned on when the motor current IMOTOR starts to rise, and is off until it is turned on in step 725 described later. If a positive determination is made here, the process proceeds to step 705.

  In step 705, the target motor current value increase amount TMIUP is set. The target motor current value increase amount TMIUP is an increase amount of the motor current IMOTOR corresponding to the target braking force calculated in step 240 of FIG. 3, more specifically, an increase amount of the motor current IMOTOR from the no-load current NOC. By causing the increase amount of the motor current IMOTOR to be the target motor current value increase amount TMIUP, it is possible to suppress an excessive W / C pressure from being generated during parking braking. This target motor current value increase amount TMIUP is set to be equal to or greater than the increase amount of the motor current IMOTOR necessary for generating the W / C pressure corresponding to the minimum brake force capable of maintaining the parking corresponding to the target brake force. .

  Here, the relationship between the W / C pressure corresponding to the target braking force and the target motor current value increase amount TMIUP is mapped, and the target motor current value corresponding to the target braking force calculated in step 240 using the map. Acquired the rising amount TMIUP. FIG. 11 is a map showing an example of such a map in which the target motor current value increase amount TMIUP increases in proportion to the magnitude of the W / C pressure corresponding to the target braking force.

  Subsequently, the routine proceeds to step 710, where it is determined whether or not the lock control time counter CLT exceeds a predetermined minimum lock control time KTLMIN. The lock control time counter CLT is a counter that measures an elapsed time since the lock control is started, and starts counting simultaneously with the start of the lock control process. The minimum lock control time KTLMIN is a minimum time assumed to be applied to the lock control, and is a value determined in advance according to the rotation speed of the motor 10 or the like. As in step 740 described later, when the motor current IMOTOR reaches a value obtained by adding the target motor current value increase amount TMIUP to the no-load current NOC, the braking force generated by the EPB2 has reached a desired value. Alternatively, the motor current IMOTOR may exceed the value (NOC + TMIUP) due to an inrush current at the initial supply of current to the motor 10 although it is determined that the current has approached. Therefore, by comparing the lock control time counter CLT with the minimum lock control time KTLMIN, the initial control period can be masked, and erroneous determination due to an inrush current or the like can be prevented.

  Therefore, if the lock control time counter CLT does not exceed the minimum time, the lock control is still continued. Therefore, the process proceeds to step 715, where the release state flag FREL is turned off and the lock control time counter CLT is set. The motor lock drive is turned on, that is, the motor 10 is rotated forward. Thereby, the brake pad 11 is moved to the brake disk 12 side with the forward rotation of the motor 10, and the locking operation by the EPB 2 is performed.

  On the other hand, if an affirmative determination is made in step 710, the process proceeds to step 720, and a current value differential value ID obtained by differentiating the motor current IMOTOR with respect to time is calculated. For example, the difference between the motor current IMOTOR obtained during the current control cycle and the previous control cycle is used as the current value differential value ID. Then, it is determined whether or not the current value differential value ID is larger than the current value differential threshold IDB.

  The motor current IMOTOR varies depending on the load applied to the motor 10. For example, in the case of the present embodiment, the load applied to the motor 10 corresponds to the pressing force pressing the brake pad 11 against the brake disk 12, and therefore has a value corresponding to the pressing force generated by the motor current IMOTOR. Therefore, when the motor 10 is in a no-load state, the motor current IMOTOR becomes a no-load current NOC, and when a load is applied to the motor 10, the motor current IMOTOR starts to increase.

  Therefore, a change in the motor current IMOTOR can be detected by obtaining a current value differential value ID obtained by differentiating the motor current IMOTOR with respect to time, and by comparing the current value differential value ID with the current value differential threshold IDB. The start of the rise of the motor current IMOTOR can be detected. It should be noted that the current value differential threshold IDB is set to a value that is assumed that the motor current IMOTOR starts to rise while excluding the noisy motor current IMOTOR fluctuation.

  If an affirmative determination is made in step 720, the current value indicating that the motor current IMOTOR has started to rise increases in step 725, the flag FIUPS is turned on, and the process proceeds to step 730. If the determination in step 720 is negative, the motor 10 is not yet loaded, so the process of step 715 is executed again.

  In step 730, after detecting the M / C pressure based on the detection signal of the M / C pressure sensor 22, whether the detected M / C pressure exceeds zero, that is, whether the M / C pressure is generated. Determine whether or not. If the M / C pressure is generated, it can be considered that the service brake 1 generates the W / C pressure according to the depression of the brake pedal 3 by the driver, and the service brake 1 generates the braking force. . If the brake force is generated by the service brake 1, the brake force generated by the EPB 2 may become larger than necessary unless the brake force is taken into consideration. Therefore, whether or not the service brake 1 is operating is determined based on whether or not the M / C pressure is generated. If an affirmative determination is made in step 730, the process proceeds to step 735 to execute a process considering the brake force generated by the service brake 1, and if a negative determination is made, the process of step 735 is not performed and step 740 is performed. Proceed to

  In step 735, the target motor current value increase amount TMIUP is corrected as a process that takes into account the amount of braking force generated by the service brake 1. That is, when the brake force is generated by the service brake 1, correction is performed to reduce the target motor current value increase amount TMIUP, and in this embodiment, the target motor current value increase amount according to the magnitude of the brake force. A subtraction value IDOWN of the target motor current value increase amount TMIUP that decreases TMIUP is obtained, and a value obtained by subtracting the subtraction value IDOWN from the target motor current value increase amount TMIUP obtained in step 705 is calculated.

  In this embodiment, the value of the subtraction value IDOWN corresponding to the M / C pressure is mapped, and the subtraction value IDOWN is obtained by extracting the value corresponding to the M / C pressure detected in step 730 based on the map. Looking for.

  FIG. 12 is a map showing an example thereof, and is a map showing the relationship between the M / C pressure and the subtraction value IDOWN. As shown in this figure, the map is such that the subtraction value IDOWN increases in proportion to the magnitude of the M / C pressure, that is, the depression (depression force) of the brake pedal 3 by the driver. For this reason, in the case of this embodiment, the subtraction value IDOWN corresponding to the M / C pressure detected in step 730 is read from the map shown in FIG. 12, and the target value is obtained by subtracting the subtraction value IDOWN from the target motor current value increase amount TMIUP. The motor current value increase amount TMIUP is obtained.

  However, it is not preferable that the target motor current value increase amount TMIUP is less than or equal to zero. For this reason, in step 735, the value obtained by subtracting the subtraction value IDOWN from the target motor current value increase amount TMIUP, or the value obtained by adding a predetermined value α (a positive constant) to the no-load current NOC, whichever is greater (MAX (TMIUP-IDOWN, NOC + α)) is used as the target motor current value increase TMIUP.

  Thereafter, the routine proceeds to step 740, where it is determined whether or not the motor current IMOTOR exceeds a value obtained by adding the target motor current value increase amount TMIUP to the no-load current NOC. When the motor current IMOTOR exceeds the value obtained by adding the target motor current value increase amount TMIUP to the no-load current NOC, the desired braking force is generated by the generated pressing force, that is, the brake pad by EPB2 The friction surface 11 is pressed against the inner wall surface of the brake disc 12 with a certain amount of force. Therefore, the process of step 715 is repeated until an affirmative determination is made in this step, and if an affirmative determination is made, the process proceeds to step 745.

  In step 745, the lock state flag FLOCK indicating that the lock is completed is turned on, the lock control time counter CLT is set to 0, and the motor lock drive is turned off (stopped). Thereby, the rotation of the motor 10 is stopped and the braking force generated at that time is held. Thereby, the movement of the parked vehicle is regulated. Further, the current value starts to increase and the flag FIUPS is turned off. In this way, the lock control process is completed.

  On the other hand, in the release control process shown in step 190 of FIG. 2, the process of operating the EPB 2 by rotating the motor 10 and releasing the braking force generated by the EPB-ECU 9 is performed. FIG. 13 is a flowchart showing details of the release control process, and the release control process will be described with reference to this figure.

  First, in step 800, the current value I (n-1) of the motor current IMOTOR detected during the previous control cycle and the current value I (n) of the motor current IMOTOR detected during the current control cycle. It is determined whether or not the absolute value of the difference | I (n−1) −I (n) | is less than the release control end determination current value RENDI.

  As described above, the motor current IMOTOR fluctuates according to the load applied to the motor 10, and when the pressing force pressing the brake pad 11 against the brake disk 12 disappears, the motor current IMOTOR is constant at the no-load current NOC. And there will be no fluctuations. For this reason, the release control end determination current value RENDI is set to a current change amount that is assumed to cause no load on the motor 10, and the absolute value | I (n-1) -I (n) | When the current value is less than RENDI, it is determined that the brake pad 11 has moved away from the brake disk 12 and the load on the motor 10 has been removed.

  Therefore, if a negative determination is made at step 800, the routine proceeds to step 805, where the lock state flag FLOCK is turned off and the motor release drive is turned on, that is, the motor 10 is rotated in the reverse direction. As a result, the brake pad 11 is moved away from the brake disc 12 with the reverse rotation of the motor 10.

  If the determination in step 800 is affirmative, the process proceeds to step 810 to increment the release control end counter CREND, and then proceeds to step 815 to determine whether or not the release control end counter CREND has exceeded the release control end time TREND. .

  The release control end time TREND is the time when the release control is continued from the timing when the load on the motor 10 is lost, the timing when the brake pad 11 is separated from the brake disk 12, and the brake pad 11 is moved by the motor 10 during the lock control. The longer the amount, the longer.

  Here, if the release control end counter CREND does not exceed the release control end time TREND, the release control is still continued, so the process of step 805 is executed. When the release control end counter CREND exceeds the release control end time TREND, the process proceeds to step 820, where the release state flag FREL, which means that the release has been completed, is turned on and the release control end counter CREND is set to 0 to drive the motor release. Turn off. Accordingly, the rotation of the motor 10 is stopped, and the brake pad 11 is held in a state of being separated from the brake disk 12. In this way, the release control process is completed.

  When the lock control process and the release control process are completed, the lock / release display process in step 150 of FIG. 2 is performed. FIG. 14 is a flowchart showing details of the lock / release display process. The lock / release display process will be described with reference to FIG.

  In step 900, it is determined whether or not the lock state flag FLOCK is turned on. If a negative determination is made here, the process proceeds to step 910 and the lock / release display lamp 23 is turned off. If an affirmative determination is made, the process proceeds to step 920 and the lock / release display lamp 23 is turned on. In this way, the lock / release display lamp 23 is turned on in the locked state, and the lock / release display lamp 23 is turned off when the release state or release control is started. As a result, it is possible to make the driver recognize whether or not the driver is locked. In this way, the lock / release display process is completed, and the parking brake control process is completed accordingly.

  FIG. 15 is a timing chart when such parking brake control processing is executed. As shown in FIG. 15 (a), when the vehicle speed is zero and the vehicle stops, the G sensor value of the G sensor 21 fluctuates due to pitching, and then the fluctuation gradually converges to correspond to the road surface gradient. Stable at the value. During this change, the target braking force is updated along the peak value of the amplitude of the G sensor output waveform as shown in FIG. For this reason, the target braking force can be made closer to a value corresponding to the road surface gradient, and the output braking force of the EPB 2 can actually be prevented from being excessively output.

  As described above, according to the vehicle brake control device of this embodiment, even when the G sensor value of the G sensor 21 fluctuates due to pitching when the vehicle speed is zero and the vehicle stops, the output waveform The target braking force is updated along the peak value of the amplitude. Thereby, the target braking force set based on the G sensor value can be made closer to a value corresponding to the road surface gradient. For this reason, it is possible to prevent an excessive braking force from being generated while preventing the vehicle from sliding down by the braking force by the EPB 2.

(Other embodiments)
(1) In the above embodiment, the motor current IMOTOR is used as the physical quantity corresponding to the pressing force of the brake pad 11 serving as the friction material to the brake disc 12 serving as the friction material, but other physical quantities such as the brake pad are used. 11 may be detected directly by a load sensor.

  (2) In the above embodiment, the case where the target motor current value increase amount TMIUP is corrected based on the M / C pressure has been described. However, another physical quantity corresponding to the braking force generated by the service brake 1 is detected, Based on this, the target motor current value increase amount TMIUP may be corrected.

  For example, the W / C pressure may be detected, or a pedal operation amount such as a stepping force or a stroke amount applied to the brake pedal 3 may be detected, and the target motor current value increase amount TMIUP may be corrected based on the detected pedal operation amount. Further, the pressing force when the brake pad 11 corresponding to the friction material is pressed against the brake disc 12 as the friction material is detected by a load sensor, or the movement amount of the brake pad 11 is detected, and the target motor is based on the detection. The current value increase amount TMIUP may be corrected.

  (3) In the above embodiment, the subtraction value IDOWN used for correcting the target motor current value increase amount TMIUP is increased as the physical amount (specifically, the M / C pressure) corresponding to the braking force by the service brake 1 increases. However, the target motor current value increase amount TMIUP may be corrected by multiplying the target motor current value increase amount TMIUP by a coefficient less than 1. The coefficient in this case may be a constant value, but when the braking force by the service brake 1 is generated, the coefficient may be made variable so that it becomes a smaller value as the physical quantity corresponding to the braking force increases.

  (4) In the above embodiment, the disc brake type EPB 2 has been described as an example, but the friction surface of the brake shoe corresponding to the friction material is adjusted to the friction material by adjusting the pressure of the wheel cylinder by driving the motor. The present invention can also be applied to a drum-type EPB 2 that presses against the inner wall surface of a brake drum corresponding to the above and generates a braking force.

  (5) In the above embodiment, each process shown in the flowcharts of FIGS. 4 to 7 is performed as a G sensor peak calculation method. However, an effective peak value may be calculated by another method. .

  (6) The steps shown in each figure correspond to means for executing various processes. That is, the part that executes the process of step 140 in FIG. 2 corresponds to the lock control target calculation means, and the part that executes the process of step 150 corresponds to the lock control means.

  DESCRIPTION OF SYMBOLS 1 ... Service brake, 2 ... EPB, 5 ... M / C, 6 ... W / C, 7 ... ESC actuator, 8 ... ESC-ECU, 9 ... EPB-ECU, 10 ... Motor, 11 ... Brake pad, 12 ... Brake Disc, 13 ... caliper, 20 ... operation SW, 21 ... G sensor, 22 ... M / C pressure sensor, 23 ... lock / release indicator lamp

Claims (3)

Driving the electric motor (10) generates a pressing force for pressing the friction material (11) against the friction material (12) attached to the wheel, and the friction material (11) and the friction material An electric parking brake (2) for generating a braking force by friction with (12);
A brake system including a service brake (1) that is actuated by operating a brake pedal (3) and moves the friction material (11) in a direction toward the friction material (12) to generate a braking force. A vehicle brake control device that controls a parking brake using
The electric motor (10) is driven to generate the pressing force to generate a braking force by the electric parking brake (2), and the electric motor is set as an end condition when the braking force reaches a target braking force. Lock control means (150) for performing a lock control to stop the driving of (10) and maintain the brake force to be in a locked state;
Lock control target calculation means (140) for setting an effective peak value along a vibration peak of an output waveform of the acceleration sensor value generated when the vehicle stops, and calculating the target braking force based on the effective peak value; A vehicle brake control device comprising:   The lock control target calculation means (140) sets the effective peak value from the peak value of the absolute value of the acceleration sensor value, and sets the first peak value among the peak values of the absolute value of the acceleration sensor value. The first effective peak value is set, and the first peak value and the second peak value of the absolute value of the acceleration sensor value are compared in magnitude. If the first peak value is larger, the effective peak value Is updated to the peak value of the absolute value of the acceleration sensor value of the odd number, and if the second time is larger, the effective peak value is updated to the peak value of the absolute value of the acceleration sensor value of the even number of times. The vehicle brake control device according to claim 1.   When the number of times the peak value of the absolute value of the acceleration sensor value is calculated for the second time or later, the lock control target calculation unit (140) calculates the acceleration sensor value when the peak value of the absolute value of the acceleration sensor value is calculated. Is updated to the peak value of the absolute value of the acceleration sensor value at the odd number of times, the sign of the acceleration sensor value when the peak value of the absolute value of the first acceleration sensor value is calculated Or when updating the peak value of the absolute value of the acceleration sensor value for the even number of times, the sign of the acceleration sensor value when calculating the peak value of the absolute value of the second time acceleration sensor value When it matches the sign, the peak of the absolute value of the acceleration sensor value regardless of whether the peak value of the absolute value of the acceleration sensor value is calculated odd or even The vehicle brake control device according to claim 2, characterized in that updating the effective peak value.

Images