JP7437949B2 - Control device and control method - Google Patents

Description

This disclosure relates to a control device and a control method that can brake a vehicle as intended by a rider even when a downshift is performed.

2. Description of the Related Art Conventionally, as a control device for controlling the behavior of a saddle-ride type vehicle such as a motorcycle, there is a control device capable of executing anti-lock brake control. According to anti-lock brake control, when the degree of slip of a wheel exceeds an upper limit value, it is possible to suppress the locking of the wheel by reducing the braking force generated on the wheel (for example, Patent Document 1).

Japanese Patent Application Publication No. 2018-024324

By the way, when a downshift is performed, the braking force from the engine brake acts on the wheels (specifically, the drive wheels), causing the wheels to slip, and anti-lock brake control may be executed. . Specifically, wheel slip caused by downshifting is resolved earlier than wheel slip caused by road surface conditions. If anti-lock brake control is executed unnecessarily in such a case, it becomes difficult to brake the vehicle as intended by the rider.

The present invention has been made against the background of the above-mentioned problems, and aims to provide a control device and a control method that can brake a vehicle as intended by a rider even when a downshift is performed.

A control device according to the present invention is a control device for controlling the behavior of a saddle-ride type vehicle, and the control device includes a control section that executes antilock brake control when the degree of slip of a wheel exceeds an upper limit value. acquires the state information of the wheel at a reference time after the start of slip of the wheel, and when the state information of the wheel is information indicating an increasing tendency of the degree of slip, changes the upper limit value from the first threshold value to the first threshold value. The anti-lock brake control is switched to a second threshold value that makes it easier to execute the anti-lock brake control compared to the first threshold value.

The control method according to the present invention is a behavior control method of a saddle-ride type vehicle, in which a control unit that executes antilock brake control when the degree of slip of a wheel exceeds an upper limit value is configured to control the anti-lock brake control after the wheel starts slipping. If the wheel condition information is information indicating an increasing tendency of the slip degree, the upper limit value is compared from a first threshold value to the first threshold value to determine the anti-lock condition. Switching to a second threshold value that makes it easier to perform brake control.

In the control device and control method according to the present invention, the control unit that executes anti-lock brake control when the slip degree of the wheel exceeds the upper limit acquires state information of the wheel at a reference time after the wheel starts slipping. However, when the state information of the wheel is information indicating an increasing tendency of the degree of slip of the wheel, the upper limit value is changed from a first threshold value to a second threshold value at which anti-lock brake control is more likely to be executed compared to the first threshold value. Switch. This prevents anti-lock brake control from being executed unnecessarily when a downshift is performed, while also appropriately executing anti-lock brake control when wheel slip occurs due to road conditions. can be done. Therefore, even when a downshift is performed, the vehicle can be braked as intended by the rider.

1 is a schematic diagram showing a schematic configuration of a motorcycle equipped with a control device according to an embodiment of the present invention. 1 is a schematic diagram showing a schematic configuration of a brake system according to an embodiment of the present invention. 1 is a block diagram showing an example of a functional configuration of a control device according to an embodiment of the present invention. FIG. 2 is a schematic diagram showing an example of the relationship between vehicle speed and engine rotation speed at each gear stage of the motorcycle according to the embodiment of the present invention. 2 is a flowchart illustrating an example of a process flow regarding switching of a slip degree upper limit value in antilock brake control performed by a control device according to an embodiment of the present invention. FIG. 3 is a schematic diagram showing changes in various state quantities when a downshift is performed while the motorcycle according to the embodiment of the present invention is running. FIG. 3 is a schematic diagram showing changes in various state quantities when wheel slip occurs due to road surface conditions while the motorcycle according to the embodiment of the present invention is running.

Below, a control device according to the present invention will be explained using the drawings.

Note that although a control device used for a two-wheeled motorcycle is described below, the control device according to the present invention is applicable to a saddle-riding type vehicle other than a two-wheeled motorcycle (for example, a three-wheeled motorcycle, a buggy, etc.). ) may be used. Note that the term "saddle type vehicle" refers to a vehicle on which a rider rides astride, and includes scooters and the like.

Further, the configuration, operation, etc. described below are merely examples, and the control device and control method according to the present invention are not limited to such configurations, operations, etc.

Further, below, the same or similar explanations are simplified or omitted as appropriate. Furthermore, in each figure, the same or similar members or portions are omitted or given the same reference numerals. Further, detailed structures are simplified or omitted as appropriate.

<Motorcycle configuration>
The configuration of a motorcycle 100 equipped with a control device 60 according to an embodiment of the present invention will be described with reference to FIGS. 1 to 3.

FIG. 1 is a schematic diagram showing a schematic configuration of a motorcycle 100 on which a control device 60 is mounted. FIG. 2 is a schematic diagram showing a schematic configuration of the brake system 10. FIG. 3 is a block diagram showing an example of the functional configuration of the control device 60.

As shown in FIG. 1, the motorcycle 100 includes a body 1, a handle 2 rotatably held on the body 1, a front wheel 3 rotatably held on the body 1 together with the handle 2, and a body 1. The rear wheel 4 is rotatably held at the rear wheel 4, and a brake system 10 is provided. In this embodiment, a control device (ECU) 60 is provided in a hydraulic pressure control unit 50 of a brake system 10, which will be described later. The motorcycle 100 also includes an engine 70, a transmission mechanism 80, a front wheel speed sensor 91, a rear wheel speed sensor 92, an engine rotation speed sensor 93, and a gear position sensor 94.

As shown in FIGS. 1 and 2, the brake system 10 includes a first brake operating section 11, a front wheel braking mechanism 12 that brakes the front wheels 3 in conjunction with at least the first brake operating section 11, and a second brake operating section 11. 13, and a rear wheel braking mechanism 14 that brakes the rear wheels 4 in conjunction with at least the second brake operating section 13. The brake system 10 also includes a hydraulic pressure control unit 50, and a portion of the front wheel braking mechanism 12 and a portion of the rear wheel braking mechanism 14 are included in the hydraulic pressure control unit 50. The hydraulic pressure control unit 50 is a unit that controls the braking force generated on the front wheels 3 by the front wheel braking mechanism 12 and the braking force generated on the rear wheels 4 by the rear wheel braking mechanism 14.

The first brake operating section 11 is provided on the handle 2 and is operated by the driver's hand. The first brake operating section 11 is, for example, a brake lever. The second brake operating section 13 is provided at the lower part of the body 1 and is operated by the driver's foot. The second brake operating section 13 is, for example, a brake pedal.

Each of the front wheel braking mechanism 12 and the rear wheel braking mechanism 14 includes a master cylinder 21 containing a piston (not shown), a reservoir 22 attached to the master cylinder 21, and a brake pad ( a brake caliper 23 having a brake caliper (not shown), a wheel cylinder 24 provided on the brake caliper 23, a main channel 25 through which brake fluid from the master cylinder 21 flows to the wheel cylinder 24, and a brake fluid from the wheel cylinder 24. A sub-flow path 26 is provided to allow the flow to escape.

The main flow path 25 is provided with an entry valve (EV) 31 . The sub flow path 26 bypasses the main flow path 25 between the wheel cylinder 24 side and the master cylinder 21 side with respect to the filling valve 31. The sub flow path 26 is provided with a release valve (AV) 32, an accumulator 33, and a pump 34 in this order from the upstream side.

The filling valve 31 is, for example, an electromagnetic valve that opens in a non-energized state and closes in a energized state. The release valve 32 is, for example, a solenoid valve that closes when not energized and opens when energized.

The hydraulic pressure control unit 50 is provided with components for controlling brake hydraulic pressure, including a fill valve 31, a release valve 32, an accumulator 33, and a pump 34, and these components are provided, and the main flow path 25 and the sub flow path 26 are connected to each other. It includes a base body 51 in which a flow path for configuration is formed, and a control device 60.

Note that the base body 51 may be formed of one member or may be formed of a plurality of members. Further, when the base body 51 is formed of a plurality of members, each component may be provided separately from different members.

The operation of the above-mentioned components of the hydraulic control unit 50 is controlled by a control device 60. Thereby, the braking force generated on the front wheels 3 by the front wheel braking mechanism 12 and the braking force generated on the rear wheels 4 by the rear wheel braking mechanism 14 are controlled.

In normal times (that is, when generating a braking force on the wheels in accordance with the driver's brake operation), the control device 60 opens the filling valve 31 and closes the releasing valve 32. In this state, when the first brake operation part 11 is operated, the piston (not shown) of the master cylinder 21 is pushed in in the front wheel braking mechanism 12, the hydraulic pressure of the brake fluid in the wheel cylinder 24 increases, and the brake caliper Brake pad 23 (not shown) is pressed against the rotor 3a of the front wheel 3, and a braking force is generated on the front wheel 3. Furthermore, when the second brake operating section 13 is operated, the piston (not shown) of the master cylinder 21 is pushed in in the rear wheel braking mechanism 14, and the hydraulic pressure of the brake fluid in the wheel cylinder 24 increases, causing the brake caliper 23 to increase. The brake pad (not shown) is pressed against the rotor 4a of the rear wheel 4, and a braking force is generated on the rear wheel 4.

The engine 70 is a drive source for the motorcycle 100 and outputs power for driving the wheels. The engine 70 is provided with, for example, one or more cylinders each having a combustion chamber formed therein, a fuel injection valve that injects fuel toward the combustion chamber, and a spark plug. When fuel is injected from the fuel injection valve, an air-fuel mixture containing air and fuel is formed in a combustion chamber, and the air-fuel mixture is ignited by a spark plug and combusts. As a result, the piston provided within the cylinder reciprocates, causing the crankshaft to rotate. Further, a throttle valve is provided in the intake pipe of the engine 70, and the amount of air taken into the combustion chamber changes depending on the throttle opening, which is the opening of the throttle valve.

A crankshaft of the engine 70 is connected to an input shaft of a transmission mechanism 80, and an output shaft of the transmission mechanism 80 is connected to the rear wheel 4. Therefore, the power output from the engine 70 is transmitted to the transmission mechanism 80, the speed is changed by the transmission mechanism 80, and the power is transmitted to the rear wheels 4, which are driving wheels. The rider can perform a shift change by operating a change pedal in a state where the clutch interposed between the crankshaft of the engine 70 and the input shaft of the transmission mechanism is released.

The front wheel speed sensor 91 is a wheel speed sensor that detects the wheel speed of the front wheel 3 (for example, the number of revolutions per unit time [rpm] of the front wheel 3 or the moving distance per unit time [km/h], etc.), Output the detection results. The front wheel speed sensor 91 may detect another physical quantity that can be substantially converted into the wheel speed of the front wheels 3. The front wheel speed sensor 91 is provided on the front wheel 3.

The rear wheel speed sensor 92 is a wheel speed sensor that detects the wheel speed of the rear wheel 4 (for example, the number of revolutions per unit time [rpm] of the rear wheel 4 or the moving distance per unit time [km/h], etc.). and outputs the detection results. The rear wheel speed sensor 92 may detect another physical quantity that can be substantially converted into the wheel speed of the rear wheels 4. The rear wheel speed sensor 92 is provided on the rear wheel 4.

The engine rotation speed sensor 93 detects the engine rotation speed (that is, the rotation speed of the engine 70) and outputs the detection result. Engine rotation speed sensor 93 is provided in engine 70, for example.

The gear position sensor 94 detects which gear stage the transmission mechanism 80 is at, and outputs the detection result. The gear position sensor 94 is provided in the transmission mechanism 80, for example.

Control device 60 controls the behavior of motorcycle 100.

For example, part or all of the control device 60 is composed of a microcomputer, a microprocessor unit, etc. Furthermore, for example, part or all of the control device 60 may be configured with something that can be updated, such as firmware, or may be a program module or the like that is executed by a command from a CPU or the like. For example, there may be one control device 60, or there may be a plurality of control devices 60.

As shown in FIG. 3, the control device 60 includes, for example, a storage section 61 and a control section 62.

The storage unit 61 stores various information used for processing performed by the control unit 62. For example, the set value of the slip degree upper limit value in anti-lock brake control, which will be described later, is stored in the storage unit 61 and rewritten by the control unit 62.

The control unit 62 controls the braking force generated on the motorcycle 100 in order to control the behavior of the motorcycle 100. In particular, the control unit 62 executes anti-lock brake control.

The control unit 62 includes, for example, an acquisition unit 62a and a brake control unit 62b.

The acquisition unit 62a acquires information from each device mounted on the motorcycle 100. For example, the acquisition unit 62a acquires information from the front wheel speed sensor 91, the rear wheel speed sensor 92, the engine rotation speed sensor 93, and the gear position sensor 94.

The brake control unit 62b controls the braking force generated at the wheels of the motorcycle 100 by controlling the operation of each component of the hydraulic pressure control unit 50 of the brake system 10.

As described above, under normal conditions, the brake control section 62b controls the operation of each component of the hydraulic pressure control unit 50 so that a braking force corresponding to the driver's brake operation is generated on the wheels.

Here, the brake control unit 62b executes anti-lock brake control when the degree of slip of the wheel exceeds an upper limit value (hereinafter also referred to as the upper limit value of slip degree). If the degree of slip of a wheel exceeds the upper limit value, the wheel may be locked or may become locked. Anti-lock brake control is control that adjusts the braking force of the wheels to a braking force that can avoid locking.

For example, the braking control unit 62b specifies the vehicle speed (that is, the speed of the vehicle body) of the motorcycle 100 based on the wheel speeds of the front wheels 3 and the rear wheels 4, and determines the vehicle speed based on the comparison result between the wheel speed of each wheel and the vehicle speed. , calculate the degree of wheel slip. The degree of slip is an index indicating the degree to which the wheels are slipping on the road surface. As the degree of slip, for example, a slip rate obtained by dividing the difference between the vehicle speed and the wheel speed by the vehicle speed is used. Note that a parameter other than the slip rate (for example, another physical quantity that can be substantially converted into the slip rate) may be used as the slip degree.

During execution of anti-lock brake control, the brake control unit 62b closes the filling valve 31 and opens the release valve 32, and in this state, drives the pump 34 to control the wheel cylinder 24. The brake fluid pressure is reduced to reduce the braking force generated on the wheels. The brake control unit 62b then closes both the filling valve 31 and the releasing valve 32 to maintain the hydraulic pressure of the brake fluid in the wheel cylinder 24 and maintain the braking force generated on the wheels. Thereafter, the brake control unit 62b opens the filling valve 31 and closes the releasing valve 32, thereby increasing the hydraulic pressure of the brake fluid in the wheel cylinder 24 and increasing the braking force generated on the wheels. The braking control unit 62b individually controls the braking force generated at the front wheels 3 and the braking force generated at the rear wheels 4 by individually controlling the operations of the front wheel braking mechanism 12 and the rear wheel braking mechanism 14. be able to.

As described above, in the control device 60, the control unit 62 executes anti-lock brake control when the degree of slip of the wheels exceeds the upper limit value (that is, the upper limit value of the slip degree). Here, the control unit 62 switches the slip degree upper limit between a first threshold and a second threshold (specifically, a threshold at which anti-lock brake control is more likely to be executed than the first threshold). As a result, even when a downshift is performed, the vehicle can be braked as intended by the rider. Processing related to switching the slip degree upper limit value in anti-lock brake control performed by the control device 60 will be described in detail later.

<Operation of control device>
The operation of the control device 60 according to the embodiment of the present invention will be described with reference to FIGS. 4 to 7.

As described above, in this embodiment, by switching the slip degree upper limit value in anti-lock brake control between the first threshold value and the second threshold value, the vehicle is adjusted as intended by the rider even when a downshift is performed. Braking is realized.

The second threshold is a threshold at which anti-lock brake control is more likely to be executed than the first threshold. That is, the second threshold is smaller than the first threshold. Here, the slip degree upper limit value is normally set to the first threshold value. The first threshold value is larger than the slip degree that is expected when a wheel (specifically, the rear wheel 4 that is a driving wheel) slips due to a downshift. That is, when the slip degree upper limit value is set to the first threshold value, unnecessary execution of anti-lock brake control is suppressed when a downshift is performed. On the other hand, in a specific case (specifically, as described later, when the status information of the rear wheels 4 is information indicating an increasing tendency of the slip degree of the rear wheels 4), the slip degree upper limit value is set to the second Can be switched to threshold. When the slip degree upper limit value is set to the second threshold value, anti-lock brake control can be appropriately executed when rear wheel 4 slips due to road surface conditions.

Here, it is preferable that the control unit 62 changes the first threshold value based on the gear stage of the motorcycle 100, for example. Specifically, the control unit 62 can change the first threshold value based on the gear position by acquiring information indicating the gear position based on the detection result of the gear position sensor 94.

FIG. 4 is a schematic diagram showing an example of the relationship between vehicle speed and engine rotation speed at each gear stage of motorcycle 100. In FIG. 4, the horizontal axis shows the vehicle speed, and the vertical axis shows the engine rotation speed. In the example shown in FIG. 4, the transmission mechanism 80 of the motorcycle 100 includes, in order from the low speed side, a first gear G1, a second gear G2, a third gear G3, a fourth gear G4, and a fifth gear. It has six gear stages: G5 and a sixth gear stage G6.

For example, as shown in FIG. 4, when the motorcycle 100 is in the third gear G3 and the vehicle speed is V2, the engine speed is N1. In this situation, when a downshift is performed and the gear changes from the third gear G3 to the second gear G2, the vehicle speed is maintained at the speed V2, while the wheel speed of the rear wheels 4 is changed to the arrow A1. As shown in , the speed first decreases from the speed V2 to the speed V1, and then increases to the speed V2 as the engine speed increases from the speed N1 to the speed N2.

As described above, when downshifting from the third gear G3, it is assumed that the slip ratio of the rear wheels 4 is approximately (V2-V1)/V2. Therefore, when the gear position is the third gear position G3, the control unit 62 sets a value such that anti-lock brake control will not be executed even if a slip rate of approximately (V2-V1)/V2 occurs. A first threshold value is set to .

Note that the control unit 62 may change the first threshold based on other parameters different from those described above.

The control unit 62 may change the first threshold value based on the vehicle speed of the motorcycle 100, for example. Specifically, the control unit 62 obtains information indicating the vehicle speed of the motorcycle 100 based on the detection results of the front wheel speed sensor 91 and the rear wheel speed sensor 92, and thereby sets the first threshold value based on the vehicle speed. It can be changed.

For example, in the example shown in FIG. 4, when the vehicle speed is V2, the gears of the motorcycle 100 are second gear G2, third gear G3, fourth gear G4, fifth gear G5, This is one of the five gear stages of the sixth gear stage G6. Here, in a gear position on the low speed side, the slip ratio of the rear wheels 4 that occurs during downshifting is greater than in a gear position on the high speed side. Therefore, the control unit 62 sets the first threshold value to a value such that anti-lock brake control is not executed even if a slip rate of an expected degree occurs when downshifting from the second gear G2, for example. do.

Further, the control unit 62 may change the first threshold value based on the engine rotation speed of the motorcycle 100, for example. Specifically, the control unit 62 changes the first threshold based on the engine speed by acquiring information indicating the engine speed of the motorcycle 100 based on the detection result of the engine speed sensor 93. Can be done.

For example, in the example shown in FIG. 4, if the engine speed is N1 and the vehicle speed is V2, the gear ratio (that is, the gear ratio) is N1/V2, which is obtained by dividing the engine speed by the vehicle speed. Identify. Then, the third gear stage G3 having a gear ratio of N1/V2 is specified as the gear stage. In this case, the control unit 62 controls the anti-lock even if a slip rate of the degree expected upon downshifting from the third gear G3 (that is, a slip rate of the order of (V2-V1)/V2) occurs. The first threshold value is set to a value such that brake control is not executed.

FIG. 5 is a flowchart illustrating an example of the flow of processing related to switching the slip degree upper limit value in antilock brake control performed by the control device 60. Specifically, the control flow shown in FIG. 5 is repeatedly performed by the control unit 62 of the control device 60. Further, step S101 and step S110 in FIG. 5 correspond to the start and end of the control flow shown in FIG. 5, respectively.

FIG. 6 is a schematic diagram showing changes in various state quantities when a downshift is performed while the motorcycle 100 is running. On the other hand, FIG. 7 is a schematic diagram showing changes in various state quantities when wheel slip occurs due to road surface conditions while the motorcycle 100 is running. In FIGS. 6 and 7, the horizontal axis represents time, and the vertical axis represents various state quantities. 6 and 7, changes in the vehicle speed Vb, which is the vehicle body speed, the wheel speed Vw of the rear wheels 4, and the wheel speed threshold value Vth are shown as various state quantities. The wheel speed threshold value Vth is a threshold value of the wheel speed Vw corresponding to the slip degree upper limit value, and the control unit 62 executes anti-lock brake control when the wheel speed Vw falls below the wheel speed threshold value Vth. In FIGS. 6 and 7, the first wheel speed threshold th1 is the threshold of the wheel speed Vw corresponding to the first threshold of the upper limit of the slip degree, and the threshold of the wheel speed Vw is the threshold of the wheel speed Vw corresponding to the second threshold of the upper limit of the slip degree. A certain second wheel speed threshold th2 is shown.

The control flow shown in FIG. 5 will be described below with reference to FIGS. 6 and 7 as appropriate. Note that the control flow shown in FIG. 5 is started in a state where the slip degree upper limit value is the first threshold value (that is, a state where the wheel speed threshold value Vth is the first wheel speed threshold value th1).

When the control flow shown in FIG. 5 is started, in step S102, the control unit 62 determines whether or not slipping of the rear wheels 4 has occurred.

For example, the control unit 62 determines whether or not slipping of the rear wheels 4 has occurred based on the wheel speed of the rear wheels 4, and sets the time when it is determined that the slipping of the rear wheels 4 has occurred as the slip occurrence point. Identify. For example, the control unit 62 determines that slipping of the rear wheels 4 has occurred when the difference between the wheel speed of the rear wheels 4 and the vehicle speed becomes larger than a reference difference, and determines the time point at which such a determination is made. Specify as the point of occurrence. The above reference difference is set to a value large enough to determine that the rear wheels 4 are slipping.

If it is determined that slipping of the rear wheels 4 has occurred (step S102/YES), the process proceeds to step S103, and the control unit 62 determines a reference time point after the rear wheels 4 start slipping. On the other hand, if it is determined that the slip of the rear wheels 4 has not occurred (step S102/NO), the determination process of step S102 is repeated.

The reference time point is the time point at which the process of step S105, which will be described later, is executed (that is, the time point at which the wheel speed Vw of the rear wheel 4 is acquired as the status information of the rear wheel 4). The control unit 62 determines the reference time based on the time when the slip occurs. For example, the control unit 62 sets the time point after the reference time Δt has elapsed from the time point at which the slip occurs as the reference time point. In this way, the time point after the reference time Δt has elapsed from the time when the slip occurred may be adopted as the reference time point.

In the example shown in FIG. 6, at time t11, the difference between the wheel speed Vw of the rear wheels 4 and the vehicle speed Vb becomes larger than the reference difference, and the control unit 62 determines that slipping of the rear wheels 4 has occurred. t11 is specified as the time point at which the slip occurs. Then, the control unit 62 sets a time point t12 after a reference time Δt has elapsed from the time point t11 as a reference time point.

In the example shown in FIG. 7, at time t21, the difference between the wheel speed Vw of the rear wheels 4 and the vehicle speed Vb becomes larger than the reference difference, and the control unit 62 determines that slipping of the rear wheels 4 has occurred. t21 is specified as the time point at which the slip occurs. Then, the control unit 62 sets a time point t22 after a reference time Δt has elapsed from the time point t21 as a reference time point.

As described above, at the reference time point, the wheel speed Vw of the rear wheels 4 is acquired as the status information of the rear wheels 4 (step S105). Then, in step S106, which will be described later, it is determined whether the status information of the rear wheels 4 is information indicating an increasing tendency of the degree of slip of the rear wheels 4. In this specification, an increasing trend means that the target physical quantity basically increases over a predetermined period of time, and a decreasing trend means that the target physical quantity basically increases over a predetermined period of time. This basically means that it will continue to decrease.

Here, if the rear wheels 4 slip due to road conditions, the degree of slip of the rear wheels 4 will continue to increase unless anti-lock brake control is executed after the slip occurs (that is, the wheel speed Vw will increase). (continues to decrease). On the other hand, when the rear wheels 4 slip due to a downshift, the degree of slip of the rear wheels 4 changes from increasing to decreasing (in other words, even if anti-lock brake control is not executed after the slip occurs) The speed Vw changes from decreasing to increasing), and the slip is eliminated.

In this embodiment, when it is determined that the status information of the rear wheels 4 is information indicating an increasing tendency of the degree of slip of the rear wheels 4, it is possible to determine that the slip of the rear wheels 4 has occurred due to the road surface condition. Focusing on the point where it is possible, the slip degree upper limit value is switched from the first threshold value to the second threshold value (specifically, the wheel speed threshold value Vth is switched from the first wheel speed threshold value th1 to the second wheel speed threshold value th2). . On the other hand, if it is determined that the status information of the rear wheels 4 is information indicating a decreasing trend in the degree of slip of the rear wheels 4, it can be determined that the slip of the rear wheels 4 has occurred due to a downshift. Focusing on this, the slip degree upper limit value is maintained at the first threshold value (specifically, the wheel speed threshold value Vth is maintained at the first wheel speed threshold value th1). Therefore, the reference time point is determined at the time point when it is assumed that the degree of slip of the rear wheels 4 tends to decrease when the rear wheels 4 slip due to downshifting.

Here, from the viewpoint of appropriately determining the reference time, it is preferable that the control unit 62 changes the reference time based on the gear position of the motorcycle 100. Specifically, the control unit 62 can change the reference time point based on the gear position by acquiring information indicating the gear position based on the detection result of the gear position sensor 94. Note that the reference time point can be adjusted, for example, by adjusting the reference time Δt.

As described above, the slip rate that occurs during downshifting may vary depending on the gear stage. Therefore, the timing at which the degree of slip of the rear wheels 4 changes from increasing to decreasing after the occurrence of slip due to downshifting may vary depending on the gear position. Therefore, for example, in the example shown in FIG. 4, when the gear stage is the third gear stage G3, the control unit 62 causes the degree of slip of the rear wheels 4 to change from increasing to decreasing after the occurrence of slip due to downshifting. The reference time is determined to be later than the expected timing for downshifting from the third gear G3.

Note that the control unit 62 may change the reference time point based on other parameters different from those described above.

The control unit 62 may change the reference time point based on the vehicle speed of the motorcycle 100, for example. Specifically, the control unit 62 changes the reference time based on the vehicle speed by acquiring information indicating the vehicle speed of the motorcycle 100 based on the detection results of the front wheel speed sensor 91 and the rear wheel speed sensor 92. can be done.

For example, in the example shown in FIG. 4, when the vehicle speed is V2, the gears of the motorcycle 100 are second gear G2, third gear G3, fourth gear G4, fifth gear G5, This is one of the five gear stages of the sixth gear stage G6. Here, in a gear on the low speed side, the slip rate of the rear wheels 4 that occurs during downshifting is greater than in a gear on the high speed side, so after the occurrence of slip, the slip rate of the rear wheels 4 decreases from increasing. The timing of the change will be delayed. Therefore, for example, the control unit 62 sets the timing at which the degree of slip changes from increasing to decreasing after the occurrence of slip due to downshifting to a point later than the timing assumed for downshifting from second gear G2. Determine the reference time point.

Further, the control unit 62 may change the reference time point based on the engine rotation speed of the motorcycle 100, for example. Specifically, the control unit 62 acquires information indicating the engine speed of the motorcycle 100 based on the detection result of the engine speed sensor 93, thereby changing the reference time point based on the engine speed. can.

For example, in the example shown in FIG. 4, when the engine speed is N1 and the vehicle speed is V2, N1/V2, which is obtained by dividing the engine speed by the vehicle speed, is specified as the gear ratio. Then, the third gear stage G3 having a gear ratio of N1/V2 is specified as the gear stage. In this case, the control unit 62 determines the timing at which the degree of slip of the rear wheels 4 changes from increasing to decreasing after the occurrence of slip due to downshifting, which is later than the timing assumed for downshifting from third gear G3. Determine the reference point so that

Note that, in the above, an example has been described in which it is determined that slipping of the rear wheels 4 has occurred when the difference between the wheel speed Vw of the rear wheels 4 and the vehicle speed Vb becomes larger than the reference difference, but the control unit 62 For example, when the wheel speed Vw of the rear wheel 4 is less than the second wheel speed threshold th2, it may be determined that the rear wheel 4 has slipped.

Further, in the above, an example in which the slip occurrence point is specified based on the wheel speed Vw of the rear wheels 4 itself has been described, but the control unit 62 may, for example, The time point at which the slip occurs may be specified based on the time change rate (the amount of change per unit time). For example, the control unit 62 determines that slipping of the rear wheels 4 has occurred when the wheel speed Vw of the rear wheels 4 has decreased and the absolute value of the time rate of change of the wheel speed Vw has become larger than a reference value. It may be determined that The above reference value is set to a value large enough to determine that the rear wheels 4 are slipping.

After step S103 in FIG. 5, in step S104, the control unit 62 determines whether a reference time point has been reached. If it is determined that the reference time has been reached (step S104/YES), the process proceeds to step S105, and the control unit 62 acquires the wheel speed Vw of the rear wheels 4 as the status information of the rear wheels 4. On the other hand, if it is determined that the reference time has not been reached (step S104/NO), the determination process of step S104 is repeated.

The status information is information used in the determination process in step S106 (specifically, the process to determine whether the degree of slip of the rear wheels 4 is increasing or decreasing). Specifically, in step S105, a plurality of data (for example, data including the wheel speed Vw detected at the reference time and the wheel speed Vw detected before the reference time) are used to determine the tendency of increase or decrease in the wheel speed Vw. group) is acquired as status information.

After step S105, in step S106, the control unit 62 determines whether the state information (that is, the wheel speed Vw of the rear wheels 4) is information indicating an increasing tendency of the degree of slip of the rear wheels 4.

Specifically, the control unit 62 determines whether the status information of the rear wheels 4 (that is, the wheel speed Vw of the rear wheels 4) is information indicating an increasing tendency of the degree of slip of the rear wheels 4. The determination is made based on the tendency of increase/decrease in the wheel speed Vw. More specifically, when the wheel speed Vw of the rear wheels 4 tends to decrease, the control unit 62 determines that the status information of the rear wheels 4 is information indicating that the degree of slip of the rear wheels 4 tends to increase. On the other hand, when the wheel speed Vw of the rear wheels 4 tends to increase, the control unit 62 determines that the status information of the rear wheels 4 is information indicating that the degree of slip of the rear wheels 4 tends to decrease.

For example, if the time rate of change in wheel speed Vw at the reference time is greater than 0, it is assumed that wheel speed Vw is increasing, and if the time rate of change in wheel speed Vw at the reference time is less than 0, wheel speed Vw is in a decreasing trend. It may be. Further, for example, if the average value of the time rate of change of the wheel speed Vw at each time point within a predetermined time period including the reference time point is greater than 0, it is assumed that the wheel speed Vw is increasing; When the average value of the time rate of change of the wheel speed Vw at each point in time is smaller than 0, the wheel speed Vw may be in a decreasing tendency.

If it is determined that the status information is not information indicating an increasing tendency of the slip degree of the rear wheels 4 (that is, the status information is information indicating a decreasing tendency of the slip degree of the rear wheels 4) (step S106/NO), The control flow shown at 5 ends. That is, in this case, the control unit 62 maintains the slip degree upper limit value at the first threshold value (specifically, maintains the wheel speed threshold value Vth at the first wheel speed threshold value th1).

In the example shown in FIG. 6, since the wheel speed Vw tends to increase at the reference time point t12, the control unit 62 determines that the status information of the rear wheels 4 is information indicating a decreasing tendency of the degree of slip of the rear wheels 4. (In other words, the determination in step S106 is NO). Therefore, after time t12, the control unit 62 maintains the wheel speed threshold Vth at the first wheel speed threshold th1. In the example shown in FIG. 6, as described above, the rear wheels 4 slip due to downshifting. In this case, as shown in FIG. 6, after time t12, anti-lock brake control is not executed, but wheel speed Vw increases and slip is eliminated. As described above, when the status information of the rear wheels 4 is information indicating a decreasing tendency of the degree of slip of the rear wheels 4, anti-lock brake control is performed by maintaining the wheel speed threshold Vth at the first wheel speed threshold th1. can be appropriately prevented from being executed unnecessarily.

If it is determined that the state information is information indicating an increasing tendency of the slip degree of the rear wheels 4 (step S106/YES), the process proceeds to step S107, and the control unit 62 changes the slip degree upper limit value from the first threshold value to the second threshold value. (Specifically, the wheel speed threshold Vth is switched from the first wheel speed threshold th1 to the second wheel speed threshold th2).

In the example shown in FIG. 7, since the wheel speed Vw tends to decrease at time t22, which is the reference time, the control unit 62 determines that the status information of the rear wheels 4 is information indicating an increasing tendency of the degree of slip of the rear wheels 4. It is determined that there is one (that is, it is determined as YES in step S106). Therefore, at time t22, the control unit 62 switches the wheel speed threshold Vth from the first wheel speed threshold th1 to the second wheel speed threshold th2. In the example shown in FIG. 7, as described above, the rear wheels 4 slip due to the road surface condition. In this case, if the anti-lock brake control is not executed, the wheel speed Vw continues to decrease, but in the example shown in FIG. 7, the wheel speed Vw exceeds the second wheel speed threshold th2 at time t23 after time t22. When the vehicle is lowered, anti-lock brake control is executed. As a result, after time t23, the wheel speed Vw changes from decreasing to increasing, and the slip is eliminated.

When it is determined as YES in step S106 in FIG. 5, in step S108 following step S107, the control unit 62 determines whether the slip degree of the rear wheels 4 has become 0 or has fallen below the lower limit value. judge.

For example, when the difference between the wheel speed Vw of the rear wheels 4 and the vehicle speed Vb becomes smaller than the reference difference, the control unit 62 determines that the slip degree of the rear wheels 4 has become 0 or has fallen below the lower limit value. The above reference difference is set to a value large enough to determine that the slip of the rear wheels 4 has been eliminated and there is no need to perform anti-lock brake control.

If it is determined that the slip degree of the rear wheels 4 has become 0 or has fallen below the lower limit (step S108/YES), the process proceeds to step S109, and the control unit 62 changes the slip degree upper limit from the second threshold to the first threshold. (specifically, the wheel speed threshold Vth is switched from the second wheel speed threshold th2 to the first wheel speed threshold th1), and the control flow shown in FIG. 5 ends. On the other hand, if it is not determined that the degree of slip of the rear wheels 4 has become 0 or has fallen below the lower limit (step S108/NO), the determination process of step S108 is repeated.

In the example shown in FIG. 7, as described above, at time t22, step S107 is executed and the wheel speed threshold Vth is switched from the first wheel speed threshold th1 to the second wheel speed threshold th2. Thereafter, at time t24, it is determined that the slip degree of the rear wheels 4 has become 0 or has fallen below the lower limit, and the control unit 62 changes the wheel speed threshold Vth from the second wheel speed threshold th2 to the first wheel speed threshold th1. Switch.

Note that although the example in which the wheel speed Vw of the rear wheels 4 is used as the status information of the rear wheels 4 has been described above, other information may be used as the status information of the rear wheels 4. For example, the control unit 62 may acquire the slip rate of the rear wheels 4 as the status information of the rear wheels 4. In this case, the control unit 62 determines whether the status information of the rear wheels 4 is information indicating an increasing tendency of the slip rate of the rear wheels 4 based on the increasing/decreasing tendency of the slip rate of the rear wheels 4. Specifically, when the slip rate of the rear wheels 4 tends to increase, the control unit 62 determines that the status information of the rear wheels 4 is information indicating that the slip rate of the rear wheels 4 tends to increase. On the other hand, if the slip rate of the rear wheels 4 is on a decreasing trend, the control unit 62 determines that the status information on the rear wheels 4 is information indicating that the slip rate of the rear wheels 4 is on a decreasing trend.

For example, if the time rate of change in the slip rate of the rear wheels 4 at the reference time is greater than 0, it is assumed that the slip rate is increasing, and if the time rate of change in the slip rate of the rear wheels 4 at the reference time is less than 0, The slip rate may be on a decreasing trend. Further, for example, if the average value of the time change rate of the slip rate of the rear wheels 4 at each point in time within a predetermined time including the reference time is larger than 0, it is determined that the slip rate is increasing, and If the average value of the time change rate of the slip rate of the rear wheels 4 at each point in time is smaller than 0, the slip rate may be decreasing.

<Effects of control device>
The effects of the control device 60 according to the embodiment of the present invention will be explained.

The control device 60 acquires the state information of the wheel at a reference time after the wheel (specifically, the rear wheel 4 that is the driving wheel) starts slipping, and the state information of the wheel indicates an increase in the degree of slip of the wheel. If the information indicates a tendency, the slip degree upper limit value is switched from the first threshold value to the second threshold value at which anti-lock brake control is more likely to be executed than the first threshold value. This prevents the anti-lock brake control from being executed unnecessarily when a downshift is performed, while also ensuring that the anti-lock brake control is properly executed when the wheels slip due to road conditions. can be executed. Therefore, even when a downshift is performed, the vehicle can be braked as intended by the rider.

Here, as another method for suppressing unnecessary execution of anti-lock brake control when a downshift is performed, the slip degree upper limit value is basically set to a second threshold value, and the gear position sensor 94 A possible method is to use the detection of a downshift based on the output as a trigger to switch the slip degree upper limit value from the second threshold value to the first threshold value. However, due to the specifications of the gear position sensor 94, the timing at which downshifting is detected may be delayed from the timing at which downshifting is actually performed. Therefore, in the method of switching the slip degree upper limit value from the second threshold value to the first threshold value using detection of a downshift as a trigger, it is possible to suppress unnecessary execution of anti-lock brake control when a downshift is performed. There are not enough ways to do that. On the other hand, in this embodiment, regardless of the specifications of the gear position sensor 94, it is possible to suppress unnecessary execution of anti-lock brake control when a downshift is performed.

Preferably, in the control device 60, the control unit 62 maintains the slip degree upper limit value at the first threshold value when the wheel state information is information indicating a decreasing tendency of the wheel slip degree. Here, if the wheel state information is information indicating a decreasing tendency of the degree of slip of the wheel, slip of the wheel has occurred due to downshifting. In this case, the slip is eliminated even if anti-lock brake control is not executed. Therefore, when the wheel state information is information indicating a decreasing tendency of the slip degree of the wheel, by maintaining the slip degree upper limit value at the first threshold value, anti-lock brake control is not executed unnecessarily. can be appropriately suppressed.

Preferably, in the control device 60, the control unit 62 controls the slip degree when the slip degree of the wheel becomes 0 or falls below the lower limit after switching the slip degree upper limit from the first threshold to the second threshold. Switching the upper limit value from the second threshold value to the first threshold value. Thereby, when the wheel slip is eliminated and there is no need to perform anti-lock brake control, the slip degree upper limit value can be returned from the second threshold value to the first threshold value.

Preferably, in the control device 60, the control unit 62 changes the first threshold value based on the gear position of the motorcycle 100. Thereby, the first threshold value can be appropriately set to a value such that anti-lock brake control is not executed even if a degree of slippage that is expected to occur during downshifting occurs. Therefore, it is possible to appropriately prevent anti-lock brake control from being executed unnecessarily when a downshift is performed. Further, the first threshold value can be appropriately changed using information indicating the gear position obtained using the gear position sensor 94.

Preferably, in the control device 60, the control unit 62 changes the first threshold value based on the vehicle speed of the motorcycle 100. Thereby, the first threshold value can be appropriately set to a value such that anti-lock brake control is not executed even if a degree of slippage that is expected to occur during downshifting occurs. Therefore, it is possible to appropriately prevent anti-lock brake control from being executed unnecessarily when a downshift is performed. Further, the first threshold value can be appropriately changed using information indicating the vehicle speed acquired using the front wheel speed sensor 91 and the rear wheel speed sensor 92.

Preferably, in the control device 60, the control unit 62 changes the first threshold value based on the engine speed of the motorcycle 100. Thereby, the first threshold value can be appropriately set to a value such that anti-lock brake control is not executed even if a degree of slippage that is expected to occur during downshifting occurs. Therefore, it is possible to appropriately prevent anti-lock brake control from being executed unnecessarily when a downshift is performed. Further, the first threshold value can be appropriately changed using information indicating the engine rotation speed acquired using the engine rotation speed sensor 93.

Preferably, in the control device 60, the control unit 62 changes the reference time based on the gear position of the motorcycle 100. Thereby, the reference time can be optimized so that it is later than the timing assumed to be the timing at which the degree of slip of the wheels changes from increasing to decreasing after the occurrence of slip due to downshifting. Therefore, it is possible to appropriately determine whether the wheel slip occurred due to the road surface condition or whether the wheel slip occurred due to downshifting, using the wheel condition information at the reference time. can. Further, the reference time point can be appropriately determined using information indicating the gear stage obtained using the gear position sensor 94.

Preferably, in the control device 60, the control unit 62 changes the reference time point based on the vehicle speed of the motorcycle 100. Thereby, the reference time can be optimized so that it is later than the timing assumed to be the timing at which the degree of slip of the wheels changes from increasing to decreasing after the occurrence of slip due to downshifting. Therefore, it is possible to appropriately determine whether the wheel slip occurred due to the road surface condition or whether the wheel slip occurred due to downshifting, using the wheel condition information at the reference time. can. Further, the reference time point can be appropriately determined using information indicating the vehicle speed acquired using the front wheel speed sensor 91 and the rear wheel speed sensor 92.

Preferably, in the control device 60, the control unit 62 changes the reference time point based on the engine rotation speed of the motorcycle 100. Thereby, the reference time can be optimized so that it is later than the timing assumed to be the timing at which the degree of slip of the wheels changes from increasing to decreasing after the occurrence of slip due to downshifting. Therefore, it is possible to appropriately determine whether the wheel slip occurred due to the road surface condition or whether the wheel slip occurred due to downshifting, using the wheel condition information at the reference time. can. Further, the reference time point can be appropriately determined using information indicating the engine rotation speed obtained using the engine rotation speed sensor 93.

Preferably, in the control device 60, the control unit 62 specifies the time point at which the wheel slip occurs, and determines the reference time point based on the time point at which the wheel slip occurs. Thereby, when slippage of the wheels occurs due to downshifting, it is possible to appropriately determine the time point at which the degree of slippage of the wheels is assumed to be decreasing as the reference time point. .

Preferably, in the control device 60, the control unit 62 identifies the time point at which the wheel slip occurs based on the wheel speed of the wheel. Thereby, the time point at which the wheel slip occurs can be appropriately identified.

Preferably, in the control device 60, the control unit 62 acquires the wheel speed of the wheel as the wheel status information, and determines whether the wheel status information is information indicating an increasing tendency of the slip degree of the wheel. is determined based on the tendency of increase/decrease in the wheel speed of the wheels. Thereby, it is possible to appropriately determine whether the wheel state information is information indicating an increasing tendency of the wheel slip rate, while omitting the process of specifying the slip rate using the wheel speed. Therefore, the process related to switching the slip degree upper limit value can be simplified.

Preferably, in the control device 60, the control unit 62 acquires a slip rate of the wheel as the wheel status information, and determines whether the wheel status information is information indicating an increasing tendency of the wheel slip rate. is determined based on the tendency of increase/decrease in the slip rate of the wheels. Thereby, it is possible to appropriately determine whether the wheel condition information is information indicating an increasing tendency of the slip degree of the wheel.

The present invention is not limited to the description of the embodiments. For example, only a portion of an embodiment may be implemented.

1 body, 2 handle, 3 front wheel, 3a rotor, 4 rear wheel, 4a rotor, 10 brake system, 11 first brake operating section, 12 front wheel braking mechanism, 13 second brake operating section, 14 rear wheel braking mechanism, 21 master cylinder, 22 reservoir, 23 brake caliper, 24 wheel cylinder, 25 main flow path, 26 sub flow path, 31 charging valve, 32 release valve, 33 accumulator, 34 pump, 50 hydraulic control unit, 51 base, 60 control device, 61 storage unit, 62 control unit, 62a acquisition unit, 62b brake control unit, 70 engine, 80 transmission mechanism, 91 front wheel speed sensor, 92 rear wheel speed sensor, 93 engine rotation speed sensor, 94 gear position sensor, 100 motor cycle.

Claims (14)

A control device (60) that controls the behavior of a saddle-ride type vehicle (100),
comprising a control unit (62) that executes anti-lock brake control when the degree of slip of the wheel (4) exceeds an upper limit;
The control unit (62)
Obtaining state information of the wheel (4) at a reference time after the wheel (4) starts slipping,
When the state information of the wheel (4) is information indicating an increasing tendency of the degree of slip, the upper limit value is compared from a first threshold value to a second threshold value at which the anti-lock brake control is more likely to be executed. switch to,
Control device. The control unit (62) maintains the upper limit value at the first threshold value when the state information of the wheel (4) is information indicating a decreasing tendency of the slip degree.
The control device according to claim 1. After switching the upper limit value from the first threshold value to the second threshold value, if the slip degree of the wheel (4) becomes 0 or falls below the lower limit value, the control unit (62) switches the upper limit value to the second threshold value. switching a value from the second threshold to the first threshold;
The control device according to claim 1 or 2. The control unit (62) changes the first threshold based on the gear stage of the saddle type vehicle (100).
The control device according to any one of claims 1 to 3. The control unit (62) changes the first threshold based on the vehicle speed of the saddle type vehicle (100).
The control device according to any one of claims 1 to 3. The control unit (62) changes the first threshold based on the engine rotation speed of the saddle type vehicle (100).
The control device according to any one of claims 1 to 3. The control unit (62) changes the reference time based on the gear stage of the saddle type vehicle (100).
The control device according to any one of claims 1 to 6. The control unit (62) changes the reference time point based on the vehicle speed of the saddle type vehicle (100).
The control device according to any one of claims 1 to 6. The control unit (62) changes the reference time point based on the engine rotation speed of the saddle type vehicle (100).
The control device according to any one of claims 1 to 6. The control unit (62) specifies the time point at which the slip of the wheel (4) occurs, and determines the reference time point based on the time point at which the slip occurs.
The control device according to any one of claims 1 to 9. The control unit (62) specifies the occurrence point based on the wheel speed of the wheel (4).
The control device according to claim 10. The control unit (62)
Obtaining the wheel speed of the wheel (4) as state information of the wheel (4),
Determining whether the state information of the wheel (4) is information indicating an increasing tendency of the slip degree based on the increasing/decreasing tendency of the wheel speed of the wheel (4).
The control device according to any one of claims 1 to 11. The control unit (62)
obtaining a slip rate of the wheel (4) as state information of the wheel (4);
Determining whether the state information of the wheel (4) is information indicating an increasing tendency of the slip rate based on the increasing/decreasing tendency of the slip rate of the wheel (4).
The control device according to any one of claims 1 to 11. A method for controlling the behavior of a saddle-riding vehicle (100), the method comprising:
A control unit (62) that executes anti-lock brake control when the degree of slip of the wheels (4) exceeds an upper limit value;
Obtaining state information of the wheel (4) at a reference time after the wheel (4) starts slipping,
When the state information of the wheel (4) is information indicating an increasing tendency of the degree of slip, the upper limit value is compared from a first threshold value to a second threshold value at which the anti-lock brake control is more likely to be executed. switch to,
Control method.

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