Patent Application
20170305432
The invention relates to a method and a device for controlling a vehicle brake to assist with departure of a vehicle and, in detail, to a method and a device for controlling a vehicle brake, capable of reliably actuating a departure assistant system to assist with departure of a vehicle, particularly, a motorcycle not only on a sloping road but also on a horizontal road (a flat road) even in the case where an expensive component, such as a gradient detection sensor, is not provided and an inexpensive component configuration is adopted.
In a vehicle, for example, a motorcycle, a conventional brake control device with a slope departure assistant system that is added with a function of assisting with slope departure adopts a configuration of using a gradient detection sensor, actuating the slope departure assistant system during a stop on an uphill road, and automatically retaining a brake pressure, and, as means for cancelling actuation of the slope departure assistant system, also adopts a configuration that when determining all types of engine information (conditions) as indicated by (i) to (iv) below are satisfied in addition to gradient information of a road surface by the gradient detection sensor, determining that a driver has an intention of departure, and automatically canceling a brake.
<Engine Information (Conditions) for Cancelling the Actuation of the Slope Departure Assistant System>
(i) An accelerator pedal position is at least equal to a specified value.
(ii) A gear position is not in neutral.
(iii) Output torque is at least equal to a specified value.
(iv) A clutch is engaged.
Meanwhile, due to the configuration of the device, relatively expensive components, such as the gradient detection sensor as well as various sensors (devices) that obtain the engine information including the accelerator pedal position, the gear position, an output torque value, a clutch state, and the like, are required for such a brake control device. As a result, cost of the device is increased, and vehicles, on which such a brake control device can be mounted, are limited.
JP-A-2012-153176 discloses a vehicle departure state estimation device that can estimate a slope departure state of the vehicle on the basis of an operation state amount of the vehicle without a relatively expensive G sensor (the gradient detection sensor) being provided, and the operation state amount of the vehicle at least includes a vehicle speed, an engine speed, an engine load, and a depression amount of an accelerator pedal.
In the motorcycle, at least one of a foot brake and a hand brake has to be actuated even on a horizontal road (a flat road), for example, when the motorcycle stops at a stop signal, a tollbooth, or the like. When the driver wishes to release both hands from a handlebar to defog or wipe off dirt on a helmet or pay fee at the tollbooth, for example, during this stop, the driver usually has to maintain such a posture that a left foot supports a vehicle body while a right foot keeps depressing a brake pedal. For this reason, the motorcycle is desirably equipped with a configuration capable of actuating a departure aid system to automatically retain the brake force even when the driver releases his/her foot from the brake pedal at departure on the horizontal road.
However, the vehicle departure state estimation device disclosed in JP-A-2012-153176 merely adopts a configuration of actuating the departure aid system only at the slope departure, and thus a configuration of actuating the departure aid system at the departure on the horizontal road, for example, is not disclosed. In addition, depending on the vehicle, such a case is assumed where only some of the engine information, such as above <Engine information (conditions) for cancelling the actuation of the slope departure assistant system> or engine information described in JP-A-2012-153176, can be used for a reason of further cost cut of the device, and the like. Thus, the brake control device for the vehicle has to be improved to have such a configuration that the departure aid system can be actuated even when only some of the engine information can be used.
The invention particularly has a purpose of providing a method and a device for controlling a vehicle brake, the method and the device capable of reliably actuating a departure assistant system to assist with departure of a vehicle, particularly, a motorcycle not only on a sloping road but also on a horizontal road even in the case where an expensive component, such as a gradient detection sensor, is not provided and an inexpensive component configuration is adopted.
In order to achieve the above purpose, a summary of a configuration of the invention is as follows.
(1) A method for controlling a vehicle brake to assist with departure of a vehicle including:
(a) detecting a stop of the vehicle;
(b) detecting brake pressures of all wheels and determining whether the brake pressure applied to at least one of all the wheels through a brake operation by a driver is at least equal to an actuation pressure;
(c) activating a departure aid system regardless of whether a road surface on which the vehicle is stopped has a gradient when it is determined that the brake pressure is at least equal to the actuation pressure;
(d) determining whether the brake pressure that is applied to a rear wheel through the brake operation by the driver is at least equal to a specified pressure that is required to stop the vehicle; and
(e) actuating the departure aid system to automatically retain the brake pressure in a state as is when the brake pressure of the rear wheel is at least equal to the specified pressure, or actuating the departure aid system, boosting the brake pressure to become at least equal to the specified pressure, and thereafter automatically retaining the brake pressure when the brake pressure of the rear wheel is lower than the specified pressure.
(2) The method for controlling the vehicle brake according to above (1) in which the specified pressure has a constant value or a variable value that varies in accordance with a road surface gradient or a road surface condition that is estimated during the stop of the vehicle.
(3) The method for controlling the vehicle brake according to above (1) or (2) further including:
(f) determining whether at least one type of vehicle information that includes an accelerator pedal position, an engine speed, and output torque information of the vehicle in an actuated state of the departure aid system is at least equal to a specified value;
(g) determining whether a specified time has elapsed in a state where the vehicle information is at least equal to the specified value; and
(h) stopping actuation of the departure aid system to automatically cancel the brake pressure of the rear wheel only when the specified time has elapsed in the state where the vehicle information is at least equal to the specified value.
(4) The method for controlling the vehicle brake according to above (3) in which the brake pressure of the rear wheel is automatically cancelled in (h) while a pressure reduction amount is adjusted in accordance with a numerical value of the vehicle information.
(5) The method for controlling the vehicle brake according to above (3) in which the brake pressure of the rear wheel is automatically cancelled in (h) while a pressure reduction amount is adjusted in accordance with a numerical value of the accelerator pedal position.
(6) The method for controlling the vehicle brake according to above (3), (4), or (5) in which the specified value of the vehicle information is a constant value or a variable value that corresponds to at least one of the road surface gradient or the road surface condition that is estimated during the stop of the vehicle.
(7) The method for controlling the vehicle brake according to above (6) in which the specified value of the vehicle information is set to a large value when the gradient that is estimated during the stop of the vehicle is an uphill, or is set to a small value when the gradient that is estimated during the stop of the vehicle is a downhill.
(8) The method for controlling the vehicle brake according to any one of above (1) to (7) in which the departure aid system is not provided with a gradient detection sensor and is actuated through the brake operation by the driver.
(9) A device for controlling a vehicle brake to assist with departure of a vehicle characterized by including:
(a) means for detecting a stop of the vehicle;
(b) means for detecting brake pressures of all wheels and determining whether the brake pressure applied to at least one of all the wheels through a brake operation by a driver is at least equal to an actuation pressure;
(c) means for activating a departure aid system regardless of whether a road surface on which the vehicle is stopped has a gradient when it is determined that the brake pressure is at least equal to the actuation pressure;
(d) means for determining whether the brake pressure that is applied to a rear wheel through the brake operation by the driver is at least equal to a specified pressure that is required to stop the vehicle; and
(e) means for actuating the departure aid system to automatically retain the brake pressure in a state as is when the brake pressure of the rear wheel is at least equal to the specified pressure, or actuating the departure aid system, boosting the brake pressure to become at least equal to the specified pressure, and thereafter automatically retaining the brake pressure when the brake pressure of the rear wheel is lower than the specified pressure.
(10) The device for controlling the vehicle brake according to above (9) in which the specified pressure has a constant value or a variable value that varies in accordance with a road surface gradient or a road surface condition that is estimated during the stop of the vehicle.
(11) The device for controlling the vehicle brake according to above (9) or (10) further including:
(f) means for determining whether at least one type of vehicle information that includes an accelerator pedal position, an engine speed, and output torque information of the vehicle in an actuated state of the departure aid system is at least equal to a specified value;
(g) means for determining whether a specified time has elapsed in a state where the vehicle information is at least equal to the specified value; and
(h) means for stopping actuation of the departure aid system to automatically cancel the brake pressure of the rear wheel only when the specified time has elapsed in the state where the vehicle information is at least equal to the specified value.
(12) The device for controlling the vehicle brake according to above (11) in which the brake pressure of the rear wheel is automatically cancelled by the means (h) while a pressure reduction amount is adjusted in accordance with a numerical value of the vehicle information.
(13) The device for controlling the vehicle brake according to above (11) in which the brake pressure of the rear wheel is automatically cancelled by the means (h) while a pressure reduction amount is adjusted in accordance with a numerical value of the accelerator pedal position.
(14) The device for controlling the vehicle brake according to the invention3 in which the specified value of the vehicle information is a constant value or a variable value that corresponds to at least one of the road surface gradient or the road surface condition that is estimated during the stop of the vehicle.
(15) The device for controlling the vehicle brake according to above (14) in which the specified value of the vehicle information is set to a large value when the gradient that is estimated during the stop of the vehicle is an uphill, or is set to a small value when the gradient that is estimated during the stop of the vehicle is a downhill.
According to the invention, the method and the device for controlling the vehicle brake can be provided, the method and the device capable of reliably actuating the departure assistant system to assist with departure of the vehicle, particularly, a motorcycle not only on a sloping road but also on a horizontal road even in the case where an expensive component, such as a gradient detection sensor, is not provided and an inexpensive component configuration is adopted.
A description will hereinafter be made on an embodiment of the invention with reference to the drawings.
First, a configuration of the front-wheel hydraulic circuit 100 will be described. The front-wheel hydraulic circuit 100 includes: a brake lever 101 that is operated by a right hand of a driver; a front-wheel side master cylinder 103 that is pressurized when the brake lever 101 is operated; a front-wheel side master cylinder reservoir 105 that is connected to the front-wheel side master cylinder 103; a front-wheel side switching valve 107 that is connected to the front-wheel side master cylinder 103 via a pipeline 104; and a front-wheel side high pressure intake valve 109 that is connected to the front-wheel side master cylinder 103 via the pipeline 104. Note that a filter is provided in each of a connection section between the pipeline 104 and the front-wheel side switching valve 107 and a connection section between the pipeline 104 and the front-wheel side high pressure intake valve 109. Furthermore, a pressure sensor 111 is provided in the pipeline 104. The pressure sensor 111 detects a pressure between the front-wheel side master cylinder 103 and each of the front-wheel side switching valve 107 and the front-wheel side high pressure intake valve 109 and transmits the pressures to an electronic control unit ECU 400, which will be described below.
In addition, a front-wheel side first inlet valve 113a is connected to the front-wheel side switching valve 107 via a pipeline 106. A filter is also provided in a connection section between the pipeline 106 and each of the front-wheel side switching valve 107 and the front-wheel side first inlet valve 113a. The front-wheel side first inlet valve 113a is connected to a front-wheel side first caliper 115a via a pipeline 114a.
Meanwhile, a front-wheel side second inlet valve 113b is directly connected to the pipeline 104. A filter is also provided in a connection section between the front-wheel side second inlet valve 113b and the pipeline 104. The front-wheel side second inlet valve 113b is connected to a front-wheel side second caliper 115b via a pipeline 114b.
Accordingly, the front-wheel side second inlet valve 113b is connected to a front-wheel brake that is actuated by the front-wheel hydraulic circuit 100 in
Meanwhile, a discharge side of the front-wheel side hydraulic pump 119 is connected to the pipeline 106 via a throttle. A suction side of the front-wheel side hydraulic pump 119 is connected to a pipeline 120 via a filter. The front-wheel side hydraulic pump 119 is driven by the DC motor 300. In addition, one end of a front-wheel side first check valve 121 is connected to the pipeline 120. Furthermore, a discharge port of the front-wheel side high pressure intake valve 109 is connected to the pipeline 120. The other end of the front-wheel side first check valve 121 is connected to a pipeline 122. The front-wheel side first check valve 121 is disposed in a manner to prevent a reverse flow from the pipeline 120 to the pipeline 122.
An inflow end of a front-wheel side first outlet valve 123a is connected to the front-wheel side first caliper 115a via the pipeline 114a. An outflow port of the front-wheel side first outlet valve 123a is connected to the pipeline 122. A filter is provided in a connection section between an inflow port of the front-wheel side first outlet valve 123a and the pipeline 114a. A pressure sensor 127a is provided in the pipeline 114a. The pressure sensor 127a measures a pressure in the pipeline 114a and transmits a pressure signal to the ECU 400.
Furthermore, an inflow port of a front-wheel side second outlet valve 123b is connected to the front-wheel side second caliper 115b via the pipeline 114b. An outflow port of the front-wheel side second outlet valve 123b is connected to the pipeline 122. A filter is provided in a connection section between the inflow port of the front-wheel side second outlet valve 123b and the pipeline 114b. A pressure sensor 127b is provided in the pipeline 114b. The pressure sensor 127b measures a pressure in the pipeline 114b and transmits a pressure signal to the ECU 400. Note that the pressure sensor 127b does not always have to be provided in the invention.
Next, a configuration of the rear-wheel hydraulic circuit 200 will be described by using
In addition, a rear-wheel side inlet valve 213 is connected to the rear-wheel side switching valve 207 via a pipeline 206. A filter is also provided in a connection section between the pipeline 206 and each of the rear-wheel side switching valve 207 and the rear-wheel side inlet valve 213. The rear-wheel side inlet valve 213 is connected to a rear-wheel side caliper 215 via a pipeline 214. A rear-wheel brake is constructed of the rear-wheel side caliper 215. As described above, the rear-wheel side caliper 215 is connected to the rear-wheel side inlet valve 213 via the pipeline 214.
Meanwhile, a discharge side of the rear-wheel side hydraulic pump 219 is connected to the pipeline 206 via a throttle. A suction side of the rear-wheel side hydraulic pump 219 is connected to a pipeline 220 via a filter. The rear-wheel side hydraulic pump 219 is driven by the DC motor 300. In addition, one end of a rear-wheel side check valve 221 is connected to the pipeline 220. Furthermore, a discharge port of the rear-wheel side high pressure intake valve 209 is connected to the pipeline 220. Moreover, the other end of the rear-wheel side check valve 221 is connected to a pipeline 222. The rear-wheel side check valve 221 is disposed in a manner to prevent a reverse flow from the pipeline 220 to the pipeline 222.
A discharge port of a rear-wheel side outlet valve 223 is connected to the pipeline 222. Furthermore, a rear-wheel side reservoir (accumulator) 225 is connected to a portion of the pipeline 222 between the rear-wheel side check valve 221 and the rear-wheel side outlet valve 223.
The rear-wheel side caliper 215 is connected to an inflow port of the rear-wheel side outlet valve 223 via the pipeline 214. An outflow port of the rear-wheel side outlet valve 223 is connected to the pipeline 222. A filter is provided in a connection section between an inflow port of the rear-wheel side outlet valve 223 and the pipeline 214. A pressure sensor 227 is provided in the pipeline 214. The pressure sensor 227 measures a pressure in the pipeline 214 and transmits a pressure signal to the ECU 400.
The hydraulic circuit that is depicted in
Furthermore, a brake pedal switch 201a that is provided on the brake pedal 201, the pressure sensors 211, 227, and a rear-wheel speed sensor 229 that detects a rear-wheel rotational speed are connected to the ECU 400. The brake pedal switch 201 transmits an operation signal of the brake pedal 201 to the ECU 400. The pressure sensors 211, 227 respectively transmit the signals indicative of the pressures in the pipelines 204, 214 to the ECU 400. The rear-wheel speed sensor 229 transmits a rear-wheel rotational speed signal to the ECU 400. In addition, if necessary, various sensors such as a radar sensor, an acceleration sensor, and a gradient sensor can also be connected to the ECU 400. However, the main purpose of the invention is to reliably actuate the departure assistant system even when the expensive component such as the gradient detection sensor is not provided and the inexpensive component configuration is adopted. Thus, it is desired to minimize an opportunity of providing the various sensors.
Based on the operation signal, the pressure signals, and the speed signal, the ECU 400 actuates each of the DC motor 300, the front-wheel side switching valve 107, the front-wheel side high pressure intake valve 109, the front-wheel side first inlet valve 113a, the front-wheel side second inlet valve 113b, the front-wheel side first outlet valve 123a, and the front-wheel side second outlet valve 123b in accordance with a specified condition. Furthermore, based on the operation signal, the pressure signals, and the speed signal, the ECU 400 actuates each of the rear-wheel side switching valve 207, the rear-wheel side high pressure intake valve 209, the rear-wheel side inlet valve 213, and the rear-wheel side outlet valve 223 in accordance with a specified condition. Note that each of the valves is an electromagnetic valve including a solenoid and opened/closed states thereof are switched when the valve is energized by the ECU 400.
Furthermore, in the brake control device of the invention, when the ECU 400 receives the rotational speed signals from the front-wheel speed sensor 129 and the rear-wheel speed sensor 229 and detects locking of the wheels during braking, the ECU 400 actuates an anti-brake lock system (ABS), actuates each of the hydraulic pumps, opens/closes each of the valves to control braking forces, and thus can prevent locking of the wheels.
In the brake control device that includes the brake hydraulic circuit depicted in
The brake control device of the invention includes a departure aid system, which will be described below. A description will hereinafter be made on control by the departure aid system according to one embodiment of the invention with reference to flowcharts depicted in
First, it is determined (detected) in step S10 whether the vehicle is stopped. A determination on whether the vehicle is stopped can be made by using any conventional technique. For example, whether the vehicle is stopped can be determined by using each of the wheel speed sensors 129, 229, or the like.
If it is determined in step S10 that the vehicle is stopped, the brake pressures of all of the wheels are next detected in step S12. Of all of the wheels (the two wheels of the front wheel and the rear wheel in the case of the motorcycle depicted in
As a method for detecting the brake pressure of the wheel, for example, the pressure sensor 111, which is provided in the pipeline 104, and the pressure sensor 211, which is provided in the pipeline 204, respectively measure hydraulic pressures of the master cylinders 103, 203 and can detect the measured hydraulic pressures of the master cylinders 103, 203 as the brake pressures. In this case, it is determined whether the brake pressure generated through braking by the driver is at least equal to the actuation pressure from measured values of the hydraulic pressures of the master cylinders 103, 203.
As another method for detecting the brake pressure of the wheel, for example, the pressure sensor 127a, which is provided in the pipeline 114a, the pressure sensor 127b, which is provided in the pipeline 114b, and the pressure sensor 227, which is provided in the pipeline 214, respectively measure hydraulic pressures of wheel cylinders and can detect the measured hydraulic pressures of the wheel cylinders as the brake pressures. In this case, it is determined whether the brake pressure generated through braking by the driver is at least equal to the actuation pressure from measured values of the hydraulic pressures of the wheel cylinders.
Then, if it is determined in step S12 that the brake pressure applied to at least one of the wheels through the brake operation by the driver, that is, in
On the other hand, if it is determined that the brake pressure applied through the tight gripping of the brake lever 101, the strong depression of the brake pedal 201, or both of these operations by the driver is at least equal to the actuation pressure, it is acknowledged that the driver wishes to automatically retain the rear-wheel brake. Then, the process proceeds to step S14, and the departure aid system is activated. At this time, the departure aid system can be activated regardless of whether a road surface on which the vehicle is stopped has a gradient, for example, not only on a sloping road but also on a horizontal road.
Note that the “actuation pressure” only has to be the brake pressure at the time when the switch of the departure aid system is turned on, and thus does not always have to be set at least equal to a brake pressure that is required to stop the vehicle on the sloping road. In addition, the departure aid system can also be set for activation in such a case where the driver performs the strong brake operation on at least one of the brake lever 101 and the brake pedal 201 for a short time and immediately cancels the brake operation as expression of the driver's intention to activate the departure aid system.
After the departure aid system is activated in step S14, it is determined in step S18 whether the brake pressure of the rear wheel that is applied through the brake operation by the driver is at least equal to a specified pressure that is required to stop the vehicle. Note that the “specified pressure” described herein is specifically a constant value or a variable value that varies in accordance with a road surface gradient or a road surface condition that is estimated during the stop of the vehicle. Setting of the specified pressure as the constant value is preferred in terms of a point that safe braking control can promptly be executed. In this case, the specified pressure may be set as the brake pressure of the rear wheel in such a degree that the vehicle can be stopped at any type of the road surface (for example, the horizontal road, an uphill road, a downhill road), more specifically, as the brake pressure of the rear wheel in such a degree that the vehicle can be stopped under the most strict stop condition, that is, on a steep road with full load capacity (two passengers and a maximum luggage load). For example, in a case of the motorcycle, for which the required brake pressure for the stop on the horizontal road is 5 bar and the required brake pressure for the stop on the steep road is 20 bar, the specified pressure is set at 20 bar regardless of the gradient of the road surface on which the motorcycle is stopped.
In addition, in the case where the specified value is set as the variable value that varies in accordance with the condition, the specified pressure can be set as the variable value that varies in accordance with the condition estimated by at least one type of the vehicle information other than that from the gradient sensor. For example, the following modes in (I) to (III) below can be raised:
(I) a case where the specified value is set as a variable value that varies in proportion to an input brake pressure by the driver;
(II) a case where the specified value is set as a variable value that varies in accordance with a relationship between the input brake pressure by the driver and deceleration of the wheel; and
(III) a case where the specified value is set as a variable value that varies in accordance with a relationship among the input brake pressure by the driver, a wheel speed, and an estimated vehicle speed that is computed.
In the case of (I), a determination on the road surface condition depends on the brake operation by the driver. Thus, the driver's intention can accurately be reflected. In addition, in the case of (II), the relationship between the input brake pressure and the deceleration is mapped for each vehicle body in advance. In this way, the gradient can be estimated from a comparison between the specified pressure and an actually detected value thereof at the stop of the vehicle (for example, the gradient is estimated as an uphill when the actual deceleration is significant with respect to the brake input, and is estimated as a downhill when the actual deceleration is insignificant). Furthermore, in the case of (III), a friction coefficient μ of the traveling road surface, in other words, whether the traveling road surface is a low μ road, that is, a bad road can be estimated from the wheel speed. Thus, “the specified pressure” can vary so as to correspond to the estimated road surface condition.
Note that, as a case where the brake pressure of the rear wheel that is applied through the brake operation by the driver becomes lower than the specified pressure, the following can be raised: (i) a case where the brake input by the driver in step S12 is performed only through the operation of the brake lever 101 and the brake pressure of the front wheel is at least equal to the actuation pressure; (ii) a case where only the brake pedal 201 is operated, and the brake pressure of the rear wheel is at least equal to the actuation pressure but is lower than the specified pressure; and (iii) a case where both of the brake lever 101 and the brake pedal 201 are operated, and the brake pressure generated through the operation of at least one of the brake lever 101 and the brake pedal 201 is at least equal to the actuation pressure, but the brake pressure of the rear wheel is lower than the specified pressure.
Here, if above (i) (or above (iii) if the brake pressure generated through the operation of the brake lever 101 in above (iii) is at least equal to the actuation pressure) is applied in step S12, the departure aid system is shifted to a front/rear wheel interlocking control mode.
If it is determined in step S18 that the brake pressure of the rear wheel is at least equal to the specified pressure, the process proceeds to step S20. Then, the departure aid system is actuated, and the brake pressure is automatically retained in a state as is. The brake pressure of the rear wheel may automatically be retained, for example, by closing the rear-wheel side switching valve 207 or by configuring the brake pedal 201 such that a lock mechanism is provided to fix the brake pedal 201 at a depressed position and thus the position of the brake pedal 201 is fixed even when the driver releases his/her foot from the brake pedal 201.
On the other hand, if it is determined in step S18 that the brake pressure of the rear wheel is lower than the specified pressure, the process proceeds to step S22. At this time, the departure aid system is actuated. The brake pressure is boosted once or is repeatedly boosted for plural times until the brake pressure becomes at least equal to the specified pressure. Thereafter, the process proceeds to step S20, and the boosted rear-wheel brake pressure is automatically retained. As a method for automatically retaining the brake pressure of the rear wheel after the brake pressure is boosted to be at least equal to the specified pressure, for example, a method for automatically retaining the brake pressure of the rear wheel to be at least equal to the specified pressure can be raised as described below. The method includes: closing the rear-wheel side switching valve 207, opening the rear-wheel intake valve 209, controlling opening/closing the rear-wheel side inlet valve 213, actuating the rear-wheel side hydraulic pump 219 using the DC motor 300, suctioning a brake fluid from the rear-wheel side master cylinder reservoir 205 via the pipeline 204 and the rear-wheel side intake valve 209, and discharging the brake fluid from the discharge port of the rear-wheel side hydraulic pump 219 through the pipeline 220 by the ECU 400, so as to boost the hydraulic pressure of the pipeline 206; and actuating the rear-wheel side caliper 215 via the rear-wheel side inlet valve 213 using the hydraulic pressure in the pipeline 206 due to such a reason that the rear-wheel side switching valve 207 is closed at this time.
The invention adopts such a configuration. Therefore, even in the case where the expensive gradient detection sensor or a sensor or a part of a device that obtains the engine information is not particularly provided and a simple device configuration is adopted, the invention can reliably actuate the departure assistant system through the expression of the driver's intention by the brake operation and can automatically retain the brake pressure of the rear wheel not only on the sloping road but also on the horizontal road even when the driver cancels the brake operation.
First, it is determined in step S20 whether at least one type of the vehicle information that includes an accelerator pedal position, an engine speed, and output torque information of the vehicle in an actuated state of the departure aid system, that is, the vehicle information of only the accelerator pedal position in
On the other hand, if it is determined that the vehicle information is at least equal to the specified value, the process proceeds to step S26. At this time, it is determined whether a specified time has elapsed in a state where the vehicle information is at least equal to the specified value. If it is determined in step S26 that the specified time has not elapsed in the state where the vehicle information is at least equal to the specified value, the process proceeds to step S30. At this time, the process returns to step S26 while the automatic retention of the rear-wheel brake pressure continues (a flow indicated by an arrow P2).
Only if it is determined in step S24 that the vehicle information is at least equal to the specified value and it is determined in step S26 that the specified time has elapsed in the state where the vehicle information is at least equal to the specified value, the process proceeds to step S28. Then, it is configured to stop the actuation of the departure aid system and automatically cancel the brake pressure of the rear wheel. That is, it is not preferred to automatically and immediately cancel the rear-wheel brake pressure when the state where the vehicle information is at least equal to the specified value is cancelled in a short time (a moment). It is because a case where the driver has no intention of departure can be assumed. For this reason, not only that the vehicle information is at least equal to the specified value but also that the specified time has elapsed in the state where the vehicle information is at least equal to the specified value are adopted as a condition that satisfies the expression of the driver's intention of the departure in the invention.
At this time, the specified values of the vehicle information, such as the accelerator pedal position, the engine speed, and the output torque information, may each be a variable value that corresponds to at least one of the road surface gradient or the road surface condition that is estimated during the stop of the vehicle.
The specified values of the vehicle information, such as the accelerator pedal position, the engine speed, and the output torque information, may each be set as a large value when it is estimated that the road surface gradient is the uphill during the stop of the vehicle, or may each be set as a small value when it is estimated that the road surface gradient is the downhill or the bad road. In this way, rapid departure or rollback of the vehicle body can be prevented. Furthermore, the specified value may vary in accordance with the estimated road surface condition.
In addition, the brake pressure of the rear wheel is preferably cancelled automatically while a pressure reduction amount is adjusted in accordance with a numerical value of the vehicle information. For example, in the case where the vehicle information is the accelerator pedal position, for example, the brake pressure of the rear wheel is preferably cancelled automatically while the pressure reduction amount is adjusted in accordance with a numerical value of the accelerator pedal position. That is, it is preferred to increase the pressure reduction amount as the numerical value of the accelerator pedal position is increased. In this way, the brake pressure can promptly be cancelled to allow the departure at rapid acceleration. In addition, it is preferred to reduce the pressure reduction amount as the numerical value of the accelerator pedal position is reduced. In this way, the brake pressure is gradually cancelled to allow the departure at normal acceleration. Furthermore, the brake pressure of the rear wheel can automatically be cancelled by adjusting the pressure reduction amount in accordance with not only the numerical value of the vehicle information but also the road surface condition that is estimated during the stop of the vehicle. In this way, brake retention and a departure aid can safely be realized without hindering feeling of braking by the driver.
In addition, the brake control device for the vehicle of the invention is configured that the departure aid system is not provided with the gradient detection sensor and has a simple device configuration that only obtains some of the vehicle information, such as the accelerator pedal position, for actuation thereof through the brake operation as the expression of the driver's intention. Therefore, cost of the device can be cut.
As it has been described so far, in the case where the vehicle is stopped on the sloping road, the brake control device for the vehicle of the invention prevents the rollback of the vehicle through the automatic retention of the brake pressure that is generated by the brake operation as the expression of the driver's intention even when the driver thereafter cancels the operation of the brake lever or the brake pedal during the stop. In addition, the brake control device for the vehicle of the invention allows the smooth departure of the vehicle by automatically canceling the brake pressure through an accelerator operation as the driver's intention. Furthermore, in the case where the vehicle is stopped on the horizontal road, the brake control device for the vehicle of the invention automatically retains the brake pressure generated through the brake operation as the expression of the driver's intention and thereby allows the driver to defog or wipe off dirt on the helmet or pay fee at a tollbooth in a state where both hands are released from the handlebar lever or the foot is released from the brake pedal. As a method for cancelling the brake pressure by stopping the actuation of the departure aid system, for example, the switching valves 107, 207 may be opened, so as to release the hydraulic pressures of the wheel cylinders.
Note that what have been described above merely exemplify the embodiment of the invention and various modifications can be made in claims. For example, the case where the brake control device of the invention is applied to the motorcycle has been described as the embodiment by using
According to the invention, the method and the device for controlling the vehicle brake can be provided, the method and the device capable of reliably actuating the departure assistant system to assist with departure of the vehicle, particularly, the motorcycle not only on the sloping road but also on the horizontal road even in the case where the expensive component, such as the gradient detection sensor, is not provided and the inexpensive component configuration is adopted.
| Number | Date | Country | Kind |
|---|---|---|---|
| 2014-207853 | Oct 2014 | JP | national |
| Filing Document | Filing Date | Country | Kind |
|---|---|---|---|
| PCT/JP2015/075348 | 9/7/2015 | WO | 00 |
