JP2019098903A - Control device of motorcycle, and control method for motorcycle - Google Patents

Abstract

PROBLEM TO BE SOLVED: To obtain a motorcycle control device capable of interlocking brake control capable of suppressing a temperature rise of a friction braking mechanism more than before. In a motorcycle control device according to the present invention, the temperature of a rear wheel friction braking mechanism is set during first interlocking brake control that generates braking force on front wheels and rear wheels when a front brake operating unit is operated. A mode selection unit for selecting the first mode A when the temperature is lower than the first specified temperature and selecting the second mode B when the temperature is higher than the first specified temperature is provided, and the amount of input to the front brake operation unit is large. When comparing the braking forces generated in the rear wheels in the first mode A and the second mode B under the same conditions, at least in a state where the input amount to the front brake operating unit is smaller than the first specified amount. The braking force generated on the rear wheels 4 in the second mode B is smaller than the braking force generated on the rear wheels in the first mode A. [Selection diagram] FIG. 4

Description

  The present invention relates to a control device of a motorcycle that performs interlocking brake control, and a control method of a motorcycle that performs interlocking brake control.

  Conventionally, a motorcycle (that is, a motorcycle or a three-wheeled motor vehicle having two front wheels and one rear wheel) for performing interlocking brake control has been proposed (see, for example, Patent Document 1). The interlocking brake control is, for example, control for generating a braking force on the front wheels when the front brake operating unit is operated, and for generating a braking force on the rear wheels even if the rear brake operating unit is not operated. In the conventional interlocking brake control, it is possible to generate a braking force corresponding to the input amount to the front brake operating unit on the rear wheel.

JP 2000-71963 A

  In the motor cycle, the heat radiation of the friction braking mechanism of the rear wheel tends to be lowered due to the rear wheel being provided at the center in the vehicle width direction or the like. The friction braking mechanism of the rear wheels is less likely to hit the wind during traveling than the friction braking mechanism of the front wheels. Here, in the conventional interlocking brake control, the braking force is always generated on both the front wheel and the rear wheel. For this reason, the temperature of the friction braking mechanism of the rear wheel tends to rise. And excessive temperature rise of the friction braking mechanism is one of the causes of failure of the friction braking mechanism. Therefore, in the conventional interlocking brake control, there is a problem that suppression of the temperature rise of the friction braking mechanism of the rear wheel is required from the viewpoint of protecting the friction braking mechanism of the rear wheel.

  The present invention is made on the background of the above-mentioned subject, and a control device of a motorcycle capable of performing interlocking brake control capable of suppressing temperature rise of a friction braking mechanism of a rear wheel more than before, and a motorcycle It is a method of control.

  The motorcycle control device according to the present invention generates the braking force on the front wheel and requests the generation of the braking force on the rear wheel when the front brake operation unit that requests the generation of the braking force on the front wheel is operated. A control device for a motorcycle that performs a first interlocking brake control that generates a braking force on the rear wheel even if a rear brake operating unit is not operated, and friction braking of the rear wheel at the time of the first interlocking brake control The first mode is selected when the temperature of the mechanism rear wheel friction braking mechanism is lower than the first specified temperature, and the second mode is selected when the temperature of the rear wheel friction braking mechanism is higher than the first specified temperature. A mode selection unit for selecting a mode is provided, and under the condition that the input amount to the front brake operation unit is the same, a blur generated on the rear wheel in the first mode When the force is compared with the braking force generated on the rear wheel in the second mode, at least the input amount to the front brake operating portion is smaller than the first prescribed amount in the second mode. The braking force generated on the rear wheel is smaller than the braking force generated on the rear wheel in the first mode.

  Further, in the motorcycle control method according to the present invention, when the front brake operation unit that requests generation of the braking force to the front wheels is operated, the braking force is generated to the front wheels and the generation of the braking force to the rear wheels is performed. A motorcycle control method for performing interlocking brake control to generate a braking force on the rear wheel even if the required rear brake operation unit is not operated, and at the time of the interlocking brake control, the friction braking mechanism of the rear wheel is used. Mode selection to select the first mode when the temperature of the rear wheel friction braking mechanism is lower than the specified temperature, and to select the second mode when the temperature of the rear wheel friction braking mechanism is higher than the specified temperature The braking force generated on the front wheels and the rear wheels are generated based on the step and the mode selected in the mode selection step A control step of controlling a rake force, the brake force generated on the rear wheel in the first mode and the rear wheel in the second mode under the condition that the input amount to the front brake operation unit is the same When the amount of input to the front brake operating unit is smaller than the specified amount when compared with the generated braking force, the braking force generated on the rear wheel in the second mode is the same as in the first mode. It is smaller than the braking force generated on the rear wheel.

  The present invention is generated at the rear wheel when the temperature of the rear wheel friction braking mechanism becomes higher than the specified temperature during interlocking brake control that generates a braking force also on the rear wheel with the operation of the front brake operation unit. By reducing the braking force, it is possible to suppress the temperature rise of the rear wheel friction braking mechanism. Therefore, the present invention can perform interlocking brake control that can suppress the temperature rise of the friction braking mechanism of the rear wheel more than in the past.

It is a figure showing composition of a motorcycle by which a control device concerning an embodiment of the invention is carried. It is a figure showing composition of a brake system of a motorcycle by which a control device concerning an embodiment of the invention is carried. It is a figure showing the system configuration of the principal part of the motorcycle by which the control device concerning an embodiment of the present invention is carried. It is an explanatory view showing an example of brake power which occurs on a rear wheel in the 1st mode and the 2nd mode which a mode selection part of a control device concerning an embodiment of the invention selects at the time of the 1st interlocking brake control. It is an explanatory view showing another example of the brake power which occurs on the rear wheel in the 1st mode and the 2nd mode which the mode selection part of the control device concerning an embodiment of the invention selects at the time of the 1st interlocking brake control. It is explanatory drawing which shows an example of the brake force generate | occur | produced in a rear wheel in the 3rd mode and 4th mode which the mode selection part of the control apparatus which concerns on embodiment of this invention selects at the time of 2nd interlocking | linkage brake control. It is explanatory drawing which shows another example of the brake force generate | occur | produced in a rear wheel in the 3rd mode and 4th mode which the mode selection part of the control apparatus which concerns on embodiment of this invention selects at the time of 2nd interlocking | linkage brake control. It is explanatory drawing which shows an example of the brake force generate | occur | produced in a front wheel in the 3rd mode and 4th mode which the mode selection part of the control apparatus which concerns on embodiment of this invention selects at the time of 2nd interlocking | linkage brake control. It is explanatory drawing which shows another example of the brake force generate | occur | produced in a front wheel in the 3rd mode and 4th mode which the mode selection part of the control apparatus which concerns on embodiment of this invention selects at the time of 2nd interlocking | linkage brake control. It is explanatory drawing which shows an example of the brake force generate | occur | produced in a front wheel in 5th mode and 6th mode which the mode selection part of the control apparatus which concerns on embodiment of this invention selects at the time of 2nd interlocking | linkage brake control. It is explanatory drawing which shows another example of the brake force generate | occur | produced in a front wheel in the 5th mode and 6th mode which the mode selection part of the control apparatus which concerns on embodiment of this invention selects at the time of 2nd interlocking | linkage brake control. It is a flowchart which shows the operation | movement at the time of the 1st interlocking brake control of the control apparatus which concerns on embodiment of this invention. It is a flowchart which shows the operation | movement at the time of the 2nd interlocking | linkage brake control of the control apparatus which concerns on embodiment of this invention.

  Hereinafter, an example of a control device and a control method according to the present invention will be described using the drawings. The configurations and operations described in the following embodiments are merely examples. The present invention is not limited to the configurations and operations described in the following embodiments. For example, although the following describes the case where the brake system has three wheel cylinders, it may have other numbers of wheel cylinders.

  Further, in the respective drawings, the same or similar members or parts will be omitted from being denoted by the reference numerals or the same reference numerals will be attached. Moreover, the illustration of the fine structure is simplified or omitted as appropriate. Further, in the following drawings, when indicating components whose drawing is omitted, they are indicated using dashed lead lines.

Embodiment.
Hereinafter, a control device according to the embodiment and an example of a motor cycle on which the control device is mounted will be described.

<Schematic configuration of control device and motor cycle on which the control device is mounted>
FIG. 1 is a view showing a configuration of a motorcycle on which a control device according to an embodiment of the present invention is mounted. FIG. 2 is a view showing a configuration of a brake system of a motorcycle on which the control device according to the embodiment of the present invention is mounted. FIG. 3 is a diagram showing a system configuration of a main part of a motorcycle on which the control device according to the embodiment of the present invention is mounted. In FIG. 2, both side surfaces of the front wheel 3 are illustrated side by side.

  As shown in FIGS. 1 and 2, the brake system 10 is mounted on a motorcycle (i.e., a motorcycle or a tricycle having two front wheels and one rear wheel) 100. The motorcycle 100 is rotatably supported by the body 1, the handle 2 rotatably supported by the body 1, the front wheel 3 rotatably supported by the body 2 with the handle 2, and the body 1 Including the rear wheel 4 that is.

  The brake system 10 includes a front brake operating unit 11, a front wheel braking mechanism 12 for braking the front wheel 3 in conjunction with at least the front brake operating unit 11, a rear brake operating unit 13, and at least a rear brake operating unit 13. And a rear wheel braking mechanism 14 for braking the rear wheel 4.

  The front brake operating unit 11 is provided on the handle 2 and is operated by the user's hand. The front brake operating unit 11 is, for example, a brake lever. The rear brake operation unit 13 is provided at the lower part of the trunk 1 and is operated by the user's foot. The rear brake operation unit 13 is, for example, a brake pedal.

  Each of the front wheel braking mechanism 12 and the rear wheel braking mechanism 14 is held by a master cylinder 21 incorporating a piston (not shown), a reservoir 22 attached to the master cylinder 21, and the body 1. The brake caliper 23 provided with the wheel cylinder 24 provided in the brake caliper 23, the main flow passage 26 for circulating the brake fluid of the master cylinder 21 to the wheel cylinder 24, and the subsidiary fluid for releasing the brake fluid of the wheel cylinder 24 A flow path 27 and a supply flow path 28 for supplying the brake fluid of the master cylinder 21 to the sub flow path 27 are included.

  The main flow path 26 is provided with a loading valve (EV) 31. The sub-passage 27 bypasses between the wheel cylinder 24 side and the master cylinder 21 side with respect to the loading valve 31 in the main flow path 26. A loosening valve (AV) 32, an accumulator 33, and a pump 34 are provided in the sub flow path 27 sequentially from the upstream side. A first valve (USV) 35 is provided between an end of the main flow passage 26 on the master cylinder 21 side and a point where the downstream end of the sub flow passage 27 is connected. The supply flow passage 28 establishes communication between the master cylinder 21 and the suction side of the pump 34 in the sub flow passage 27. The supply flow path 28 is provided with a second valve (HSV) 36.

  The loading valve 31 is, for example, an electromagnetic valve that opens in a non-energized state and closes in an energized state. The loosening valve 32 is, for example, a solenoid valve that is closed in the non-energized state and opened in the energized state. The first valve 35 is, for example, an electromagnetic valve that opens in a non-energized state and closes in an energized state. The second valve 36 is, for example, an electromagnetic valve that closes in a non-energized state and opens in an energized state.

  The members such as the loading valve 31, the loosening valve 32, the accumulator 33, the pump 34, the first valve 35, the second valve 36 and the like are provided, and the main flow passage 26, the sub flow passage 27 and the supply flow passage 28 A fluid pressure control unit 50 is configured by a base 51 having a flow path to be formed therein and a control unit (ECU) 60. The fluid pressure control unit 50 controls the fluid pressure of the brake fluid of the wheel cylinder 24 in the brake system 10, that is, the braking force of the front wheel 3 generated in the front wheel braking mechanism 12 and the rear wheel 4 generated in the rear wheel braking mechanism 14. The unit is responsible for controlling the braking force of the

  The respective members may be collectively provided on one base 51, or may be separately provided on a plurality of bases 51. Moreover, the control apparatus 60 may be one, and may be divided into plurality. In addition, the control device 60 may be attached to the base 51 or may be attached to another member other than the base 51. Further, part or all of the control device 60 may be configured by, for example, a microcomputer, a microprocessor unit, or the like, or may be configured by an updatable device such as firmware, or an instruction from a CPU or the like. It may be a program module or the like executed by

  The control device 60 controls the loading valve 31, the loosening valve 32, the first valve 35 and the second valve 36 as follows during normal brake control. The normal brake control is a control that generates the braking force only on the front wheel 3 when the front brake operation unit 11 that requests the generation of the braking force on the front wheel 3 is operated. Further, the normal brake control is control for causing only the rear wheel 4 to generate a braking force when the rear brake operation unit 13 that requests generation of a braking force to the rear wheel 4 is operated.

  Specifically, at the time of normal brake control, the control device 60 opens the loading valve 31, closes the loosening valve 32, opens the first valve 35, and closes the second valve 36. In that state, when the front brake operation unit 11 is operated, the piston (not shown) of the master cylinder 21 is pushed in the front wheel braking mechanism 12 to increase the hydraulic pressure of the brake fluid of the wheel cylinder 24, and the brake caliper 23 The brake pad 25 provided on the front wheel 3 is pressed against the rotor 3 a of the front wheel 3. Thereby, a braking force is generated on the front wheel 3 and the front wheel 3 is braked. Further, when the rear brake operation unit 13 is operated, the piston (not shown) of the master cylinder 21 is pushed in the rear wheel braking mechanism 14 to increase the hydraulic pressure of the brake fluid of the wheel cylinder 24. The provided brake pad 25 is pressed against the rotor 4 a of the rear wheel 4. Thereby, a braking force is generated on the rear wheel 4 and the rear wheel 4 is braked.

  That is, in the brake system 10 according to the present embodiment, the friction braking mechanism 29, which is a mechanism that generates a frictional force for braking the wheels, includes a rotor provided on the wheels, a brake pad 25 pressed against the rotor, and a brake. It is comprised by the brake caliper 23 grade | etc., In which the pad 25 was provided. In other words, the friction braking mechanism 29 according to the present embodiment includes the rotor, the brake pad 25 and the brake caliper 23. More specifically, the friction braking mechanism 29 that generates the frictional force for braking the front wheel 3 includes the rotor 3 a of the front wheel 3, the brake pad 25 of the front wheel braking mechanism 12, and the brake caliper 23 of the front wheel braking mechanism 12. Further, the friction braking mechanism 29 that generates a frictional force for braking the rear wheel 4 includes the rotor 4 a of the rear wheel 4, the brake pad 25 of the rear wheel braking mechanism 14, and the brake caliper 23 of the rear wheel braking mechanism 14. ing. Hereinafter, the friction braking mechanism 29 that generates the frictional force for braking the front wheel 3 will be referred to as the friction braking mechanism 29 of the front wheel 3. Also, the friction braking mechanism 29 that generates the friction force for braking the rear wheel 4 will be referred to as the friction braking mechanism 29 of the rear wheel 4.

  In the brake system 10 according to the present embodiment, the friction braking mechanism 29 is a disc brake type. However, the friction braking mechanism 29 is not limited to the disc brake type. For example, in the case where the friction braking mechanism 29 is of a drum brake type, the friction braking mechanism 29 is configured of a brake drum provided on a wheel, and a brake shoe or the like pressed against the brake drum.

  The control device 60 also performs interlocking brake control. The interlocking brake control is a control that causes the front wheel 3 to generate a braking force when the front brake operating unit 11 is operated and causes the rear wheel 4 to generate a braking force even if the rear brake operating unit 13 is not operated. is there. Hereinafter, the interlocking brake control is referred to as first interlocking brake control. Further, with interlocked brake control, when the rear brake operating unit 13 is operated, the rear wheel 4 generates a braking force, and even when the front brake operating unit 11 is not operated, the front wheel 3 generates a braking force. It is control. Hereinafter, the interlocking brake control is referred to as second interlocking brake control.

  For example, at the time of interlocking brake control, the control device 60 controls the loading valve 31, the loosening valve 32, the first valve 35, the second valve 36, and the pump 34 as follows. At the time of the first interlocking brake control, in the front wheel braking mechanism 12, the loading valve 31 is opened, the loosening valve 32 is closed, the first valve 35 is opened, and the second valve 36 is closed. Then, at the time of the first interlocking brake control, in the rear wheel braking mechanism 14, the loading valve 31 is opened, the loosening valve 32 is closed, the first valve 35 is closed, and the second valve 36 is opened, The pump 34 is driven. Further, at the time of the second interlocking brake control, in the rear wheel braking mechanism 14, the loading valve 31 is opened, the loosening valve 32 is closed, the first valve 35 is opened, and the second valve 36 is closed. Then, at the time of the second interlocking brake control, in the front wheel braking mechanism 12, the loading valve 31 is opened, the loosening valve 32 is closed, the first valve 35 is closed, and the second valve 36 is opened. 34 are driven.

  As shown in FIGS. 2 and 3, the brake system 10 includes a master cylinder pressure sensor 41, a wheel cylinder pressure sensor 42, a front wheel rotational speed sensor 43, and a rear wheel rotational speed sensor 44.

  Master cylinder pressure sensor 41 detects the fluid pressure of the brake fluid of master cylinder 21. Master cylinder pressure sensor 41 may detect another physical quantity that can be substantially converted to the hydraulic pressure of the brake fluid of master cylinder 21. Master cylinder pressure sensor 41 is provided for each of front wheel braking mechanism 12 and rear wheel braking mechanism 14.

  The wheel cylinder pressure sensor 42 detects the fluid pressure of the brake fluid of the wheel cylinder 24. The wheel cylinder pressure sensor 42 may detect another physical quantity that can be substantially converted to the fluid pressure of the brake fluid of the wheel cylinder 24. The wheel cylinder pressure sensor 42 is provided to each of the front wheel braking mechanism 12 and the rear wheel braking mechanism 14.

  The front wheel rotational speed sensor 43 detects the rotational speed of the front wheel 3. The front wheel rotational speed sensor 43 may detect another physical quantity that can be substantially converted to the rotational speed of the front wheel 3. The rear wheel rotational speed sensor 44 detects the rotational speed of the rear wheel 4. The rear wheel rotational speed sensor 44 may detect another physical quantity that can be substantially converted to the rotational speed of the rear wheel 4.

  Control device 60 includes a temperature acquisition unit 61, a mode selection unit 62, and a control unit 63. The control device 60 receives detection results of various sensors such as the master cylinder pressure sensor 41, the wheel cylinder pressure sensor 42, the front wheel rotational speed sensor 43, and the rear wheel rotational speed sensor 44.

  The temperature acquisition unit 61 is a functional unit that acquires the temperature of the friction braking mechanism 29 of the front wheel 3 and the temperature of the friction braking mechanism 29 of the rear wheel 4. In the present embodiment, the temperature acquiring unit 61 acquires the temperature of the brake pad 25 provided on the brake caliper 23 of the front wheel braking mechanism 12 as the temperature of the friction braking mechanism 29 of the front wheel 3. Further, in the present embodiment, the temperature acquiring unit 61 acquires the temperature of the brake pad 25 provided on the brake caliper 23 of the rear wheel braking mechanism 14 as the temperature of the friction braking mechanism 29 of the rear wheel 4. There is. Hereinafter, the brake pad 25 provided on the brake caliper 23 of the front wheel braking mechanism 12 will be referred to as the brake pad 25 of the front wheel 3. Also, the brake pad 25 provided on the brake caliper 23 of the rear wheel braking mechanism 14 will be referred to as the brake pad 25 of the rear wheel 4.

  Specifically, the temperature acquisition unit 61 calculates the temperature of the brake pad 25 of the front wheel 3 using the detection value of the wheel cylinder pressure sensor 42 of the front wheel braking mechanism 12 and the detection value of the front wheel rotational speed sensor 43 . Further, the temperature acquisition unit 61 calculates the temperature of the brake pad 25 of the rear wheel 4 using the detection value of the wheel cylinder pressure sensor 42 of the rear wheel braking mechanism 14 and the detection value of the rear wheel rotational speed sensor 44. ing. The method of calculating the temperature of the brake pad of the wheel based on the hydraulic pressure of the brake fluid of the wheel cylinder and the wheel rotational speed is a known method, for example, as used in the field of four-wheeled vehicles and the like. is there. Therefore, in the present embodiment, the description of a specific method of calculating the temperature of the brake pad 25 of the front wheel 3 and the description of the specific method of calculating the temperature of the brake pad 25 of the rear wheel 4 will be omitted.

  In addition, the method of acquiring the temperature of the brake pad 25 of the front wheel 3 is arbitrary. For example, a temperature sensor may be attached to the brake pad 25 of the front wheel 3 to directly detect the temperature of the brake pad 25 of the front wheel 3. Further, for example, a temperature sensor is attached to a part provided in the vicinity of the brake pad 25 of the front wheel 3 and affected by the temperature of the brake pad 25 of the front wheel 3, and the temperature of the brake pad 25 of the front wheel 3 is It may be calculated. Further, for example, the temperature of the brake pad 25 of the front wheel 3 may be calculated based on the pressure of the front wheel 3. Specifically, when a braking force is generated on the front wheel 3 and the front wheel 3 is braked, the temperature of the brake pad 25 of the front wheel 3 rises, and the temperature of the front wheel 3 also rises due to the friction between the front wheel 3 and the road surface. Then, as the temperature of the front wheel 3 rises, the air in the front wheel 3 expands and the pressure of the front wheel 3 also rises. For this reason, it is also possible to calculate the temperature of the brake pad 25 of the front wheel 3 based on the pressure of the front wheel 3. Further, for example, the temperature of the brake pad 25 of the front wheel 3 may be calculated based on the number of times of use of the front wheel 3 per unit time. A relative relationship can be found between the number of times the front wheel 3 is used per unit time and the temperature of the brake pad 25 of the front wheel 3. For this reason, it is also possible to calculate the temperature of the brake pad 25 of the front wheel 3 based on the number of times of use of the front wheel 3 per unit time.

  Further, the temperature of the friction braking mechanism 29 of the front wheel 3 is not limited to the temperature of the brake pad 25 of the front wheel 3. For example, the temperature of the configuration other than the brake pad 25 constituting the friction braking mechanism 29 of the front wheel 3 may be acquired as the temperature of the friction braking mechanism 29 of the front wheel 3. The components other than the brake pad 25 constituting the friction braking mechanism 29 of the front wheel 3 are, for example, the brake caliper 23 of the front wheel braking mechanism 12 or the like. Under the present circumstances, the method of acquiring the temperature of these structures is arbitrary.

  Similarly, the method of acquiring the temperature of the brake pad 25 of the rear wheel 4 is also arbitrary. For example, a temperature sensor may be attached to the brake pad 25 of the rear wheel 4 to directly detect the temperature of the brake pad 25 of the rear wheel 4. Further, for example, a temperature sensor is attached to a part provided in the vicinity of the brake pad 25 of the rear wheel 4 and affected by the temperature of the brake pad 25 of the rear wheel 4, and the detected value of the temperature sensor detects the brake pad 25 of the rear wheel 4 The temperature of may be calculated. Further, for example, the temperature of the brake pad 25 of the rear wheel 4 may be calculated based on the pressure of the rear wheel 4. Further, for example, the temperature of the brake pad 25 of the rear wheel 4 may be calculated based on the number of times of use of the rear wheel 4 per unit time. Further, as the temperature of the friction braking mechanism 29 of the rear wheel 4, the temperature of a configuration other than the brake pad 25 constituting the friction braking mechanism 29 of the rear wheel 4 may be acquired. The components other than the brake pad 25 constituting the friction braking mechanism 29 of the rear wheel 4 are, for example, the brake caliper 23 of the rear wheel braking mechanism 14 and the like. Under the present circumstances, the method of acquiring the temperature of these structures is arbitrary.

  The mode selection unit 62 selects the control mode of the brake from the normal brake control mode and the interlocked brake control mode. The normal brake control mode is a control mode in which normal brake control is performed. The interlocking brake control mode is a control mode in which interlocking brake control is performed. The mode selection unit 62 selects the control mode of the brake from the normal brake control mode and the interlocked brake control mode, for example, based on the rider's request input by the switch.

  When at least one of front brake operating unit 11 and rear brake operating unit 13 is operated, control unit 63 sets loading valve 31 and slackening valve 32 according to the control mode selected by mode selection unit 62. , The first valve 35, the second valve 36 and the pump 34 are controlled.

  Here, in the conventional interlocking brake control, the braking force is always generated on both the front wheel and the rear wheel. Therefore, in the conventional interlocking brake control, the temperature of the friction braking mechanism tends to rise. And excessive temperature rise of the friction braking mechanism is one of the causes of failure of the friction braking mechanism. In particular, generally in the motorcycle, the temperature of the friction braking mechanism of the rear wheel is likely to be higher than that of the friction braking mechanism of the front wheel. The friction braking mechanism of the rear wheels is less likely to hit the wind during traveling than the friction braking mechanism of the front wheels. For this reason, in the conventional interlocking brake control, in particular, the temperature of the friction braking mechanism of the rear wheel tends to rise. Therefore, in the conventional interlocking brake control, from the viewpoint of protecting the friction braking mechanism of the rear wheel, it is required to suppress the temperature rise of the friction braking mechanism of the rear wheel.

  Therefore, the mode selection unit 62 of the control device 60 of the motorcycle 100 according to the present embodiment suppresses the temperature rise of the friction braking mechanism 29 of the rear wheel 4 during the first interlocking brake control more than in the prior art. Mode A or second mode B is selected.

  FIG. 4 is an explanatory view showing an example of the braking force generated on the rear wheel in the first mode and the second mode selected by the mode selection unit of the control device according to the embodiment of the present invention at the first interlocking brake control. is there. In addition, FMP shown to the horizontal axis of FIG. 4 is an abbreviation of Front Master Pressure, and is a hydraulic pressure of the brake fluid of the master cylinder 21 which the master cylinder pressure sensor 41 of the front wheel braking mechanism 12 detects. That is, the horizontal axis in FIG. 4 indicates the amount of input to the front brake operating unit 11 of the rider. Further, RWP shown on the vertical axis of FIG. 4 is an abbreviation of Rear Wheel Pressure, which is a hydraulic pressure of the brake fluid of the wheel cylinder 24 detected by the wheel cylinder pressure sensor 42 of the rear wheel braking mechanism 14. That is, the vertical axis in FIG. 4 indicates the braking force generated on the rear wheel 4. Further, the broken line shown in FIG. 4 indicates the first mode A, and the solid line shown in FIG. 4 indicates the second mode B.

  Specifically, the mode selection unit 62 selects the first mode A when the temperature of the friction braking mechanism 29 of the rear wheel 4 is lower than the first specified temperature at the time of the first interlocking brake control. Further, the mode selection unit 62 selects the second mode B when the temperature of the friction braking mechanism 29 of the rear wheel 4 is higher than the first specified temperature at the time of the first interlocking brake control. Then, when the braking force generated on the rear wheel 4 in the first mode A is compared with the braking force generated on the rear wheel 4 in the second mode B under the same condition as the input amount to the front brake operation unit 11: The braking force generated on the rear wheel 4 in the second mode B is smaller than the braking force generated on the rear wheel 4 in the first mode A. Note that the magnitude of the braking force generated on the rear wheel 4 at the time of the first interlocking brake control is, for example, the number of revolutions of the drive source (motor etc.) of the pump 34 of the rear wheel braking mechanism 14 and the loading valve of the rear wheel braking mechanism 14 Adjustment can be performed by controlling at least one of the opening degree 31 and the opening time of the loading valve 31 of the rear wheel braking mechanism 14.

  At the time of the first interlocking brake control, the state of the temperature of the friction braking mechanism 29 of the rear wheel 4 is higher than the first specified temperature by the mode selection unit 62 selecting the first mode A or the second mode B as described above When it becomes, the braking force generated on the rear wheel 4 can be reduced. That is, by selecting the second mode B, the temperature rise of the friction braking mechanism 29 of the rear wheel 4 can be suppressed. For this reason, at the time of the first interlocking brake control, the mode selection unit 62 selects the first mode A or the second mode B as described above, thereby suppressing the temperature rise of the friction braking mechanism 29 of the rear wheel 4 more than before. can do. Therefore, at the time of the first interlocking brake control, the interlocking brake control can protect the friction braking mechanism 29 of the rear wheel 4 more than before by the mode selection unit 62 selecting the first mode A or the second mode B as described above. It can be performed.

  In FIG. 4, in the second mode B, the rear wheel 4 is configured not to generate a braking force. However, the second mode B shown in FIG. 4 is merely an example. For example, in the second mode B, a braking force may be generated on the rear wheel 4. That is, when the braking force generated on the rear wheel 4 in the first mode A is compared with the braking force generated on the rear wheel 4 in the second mode B under the same condition as the input amount to the front brake operation unit 11: The braking force generated on the rear wheel 4 in the second mode B may be smaller than the braking force generated on the rear wheel 4 in the first mode A. Also, for example, the second mode B may be configured as follows.

  FIG. 5 shows another example of the braking force generated on the rear wheel in the first mode and the second mode selected by the mode selection unit of the control device according to the embodiment of the present invention at the time of the first interlocking brake control. FIG. The horizontal and vertical axes in FIG. 5 are the same as those in FIG. Further, the pressure P1 detected by the master cylinder pressure sensor 41 of the front wheel braking mechanism 12 that indicates the amount of input to the front brake operation unit 11 corresponds to a first prescribed amount of the present invention.

  The ratio of the braking force generated on the rear wheel 4 in the first mode A to the braking force generated on the rear wheel 4 in the second mode B under the same condition as the input amount to the front brake operation unit 11 is defined as the first ratio Do. For example, a certain input amount to the front brake operation unit 11 is set as a detected pressure P of the master cylinder pressure sensor 41 of the front wheel braking mechanism 12. When the input amount to the front brake operating unit 11 is P in the second mode B, the hydraulic pressure of the brake fluid of the wheel cylinder 24 detected by the wheel cylinder pressure sensor 42 of the rear wheel braking mechanism 14 is PB. . In the first mode A, when the input amount to the front brake operation unit 11 is P, the hydraulic pressure of the brake fluid of the wheel cylinder 24 detected by the wheel cylinder pressure sensor 42 of the rear wheel braking mechanism 14 is PA. . In this case, the first ratio when the input amount to the front brake operation unit 11 is P is a value obtained by dividing PA by PB. That is, the first ratio when the input amount to the front brake operation unit 11 is P is PA / PB. That is, in the second mode B, the reduction amount of the braking force generated on the rear wheel 4 with respect to the first mode A decreases as the first ratio decreases.

  When the first ratio is defined as described above, the first ratio in the state where the pressure detected by the master cylinder pressure sensor 41 of the front wheel braking mechanism 12 is larger than P1 is the pressure detected by the master cylinder pressure sensor 41 of the front wheel braking mechanism 12 Is smaller than the first ratio in the state smaller than P1. That is, in the second mode B shown in FIG. 5, when the pressure detected by master cylinder pressure sensor 41 of front wheel braking mechanism 12 becomes larger than P1, the pressure detected by master cylinder pressure sensor 41 of front wheel braking mechanism 12 is P1. A large braking force is generated on the rear wheel 4 as compared with a smaller state.

  When it is desired to stop the motorcycle 100 suddenly, the amount of input to the front brake operating unit 11 of the rider becomes large. By configuring the second mode B as shown in FIG. 5, when it is desired to stop the motorcycle 100 rapidly, the rear wheel 4 can also be used in the second mode B in which the temperature rise of the friction braking mechanism 29 of the rear wheel 4 is suppressed. Sufficient braking force can be generated to improve the safety of the motorcycle 100. Further, by configuring the second mode B as shown in FIG. 5, the friction braking mechanism 29 of the rear wheel 4 can be configured as in the prior art at least when the pressure detected by the master cylinder pressure sensor 41 of the front wheel braking mechanism 12 is smaller than P1. It is possible to perform interlocking brake control that can be more protected.

  In the second mode B shown in FIG. 5, when the pressure detected by the master cylinder pressure sensor 41 of the front wheel braking mechanism 12 is larger than P1, the braking force generated on the rear wheel 4 is the first mode. In A, it is the same as the braking force generated on the rear wheel 4. However, this is just an example. When the pressure detected by the master cylinder pressure sensor 41 of the front wheel braking mechanism 12 is larger than P1, the braking force generated on the rear wheel 4 in the second mode B is generated on the rear wheel 4 in the first mode A It may be smaller than the required braking force.

  Further, the mode selection unit 62 of the control device 60 suppresses the temperature rise of the friction braking mechanism 29 of the rear wheel 4 even during the second interlocking brake control than in the conventional case, so the third mode C or the third mode C or The fourth mode D is selected.

  FIG. 6 is an explanatory view showing an example of the braking force generated on the rear wheel in the third mode and the fourth mode selected by the mode selection unit of the control device according to the embodiment of the present invention at the second interlocking brake control. is there. RMP shown on the horizontal axis of FIG. 6 is an abbreviation of Rear Master Pressure, and is the hydraulic pressure of the brake fluid of the master cylinder 21 detected by the master cylinder pressure sensor 41 of the rear wheel braking mechanism 14. That is, the horizontal axis in FIG. 6 indicates the amount of input to the rear brake operation unit 13 of the rider. Further, RWP shown on the vertical axis of FIG. 6 is the hydraulic pressure of the brake fluid of the wheel cylinder 24 detected by the wheel cylinder pressure sensor 42 of the rear wheel braking mechanism 14 as in FIG. That is, the vertical axis in FIG. 6 indicates the braking force generated on the rear wheel 4. Further, a broken line shown in FIG. 6 indicates the third mode C, and a solid line shown in FIG. 6 indicates the fourth mode D.

  Specifically, the mode selection unit 62 selects the third mode C when the temperature of the friction braking mechanism 29 of the rear wheel 4 is lower than the second specified temperature at the time of the second interlocking brake control. Further, the mode selection unit 62 selects the fourth mode D when the temperature of the friction braking mechanism 29 of the rear wheel 4 is higher than the second specified temperature at the time of the second interlocking brake control. Then, when the braking force generated on the rear wheel 4 in the third mode C is compared with the braking force generated on the rear wheel 4 in the fourth mode D under the same condition as the input amount to the rear brake operating unit 13: The braking force generated on the rear wheel 4 in the fourth mode D is smaller than the braking force generated on the rear wheel 4 in the third mode C. The magnitude of the braking force generated on the rear wheel 4 at the time of the second interlocking brake control is, for example, the opening degree of the loading valve 31 of the rear wheel braking mechanism 14 and the opening time of the loading valve 31 of the rear wheel braking mechanism 14. Adjustment can be made by controlling at least one of them.

  At the time of the second interlocking brake control, when the mode selection unit 62 selects the third mode C or the fourth mode D as described above, the temperature of the friction braking mechanism 29 of the rear wheel 4 is higher than the second specified temperature When it becomes, the braking force generated on the rear wheel 4 can be reduced. That is, by selecting the fourth mode D, the temperature rise of the friction braking mechanism 29 of the rear wheel 4 can be suppressed. For this reason, at the time of the second interlocking brake control, the mode selection unit 62 selects the third mode C or the fourth mode D as described above to suppress the temperature rise of the friction braking mechanism 29 of the rear wheel 4 more than before. can do. Therefore, at the time of the second interlocking brake control, the interlocking brake control can protect the friction braking mechanism 29 of the rear wheel 4 more than before by the mode selection unit 62 selecting the third mode C or the fourth mode D as described above. It can be performed.

  In the case where the braking force of the rear wheel 4 is given priority over the suppression of the temperature rise of the friction braking mechanism 29 of the rear wheel 4 under the condition that the motor cycle 100 is to be suddenly stopped, the fourth mode D is configured as follows May be

  FIG. 7 illustrates another example of the braking force generated on the rear wheel in the third mode and the fourth mode selected by the mode selection unit of the control device according to the embodiment of the present invention at the time of the second interlocking brake control FIG. The horizontal and vertical axes in FIG. 7 are the same as in FIG. Further, the pressure P2 detected by the master cylinder pressure sensor 41 of the rear wheel braking mechanism 14 that indicates the amount of input to the rear brake operation unit 13 corresponds to a second prescribed amount of the present invention.

  The ratio of the braking force generated on the rear wheel 4 in the third mode C to the braking force generated on the rear wheel 4 in the fourth mode D under the same condition as the input amount to the rear brake operation unit 13 is defined as the second ratio Do. For example, a certain input amount to the rear brake operation unit 13 is set as a detected pressure P of the master cylinder pressure sensor 41 of the rear wheel braking mechanism 14. When the input amount to the rear brake operation unit 13 is P in the fourth mode D, the hydraulic pressure of the brake fluid of the wheel cylinder 24 detected by the wheel cylinder pressure sensor 42 of the rear wheel braking mechanism 14 is PD. . In the third mode C, when the input amount to the rear brake operation unit 13 is P, the hydraulic pressure of the brake fluid of the wheel cylinder 24 detected by the wheel cylinder pressure sensor 42 of the rear wheel braking mechanism 14 is PC. . In this case, the second ratio when the input amount to the rear brake operating unit 13 is P is a value obtained by dividing PC by PD. That is, the second ratio when the input amount to the rear brake operation unit 13 is P is PC / PD. That is, in the fourth mode D, the reduction amount of the braking force generated on the rear wheel 4 with respect to the third mode C decreases as the second ratio decreases.

  When the second ratio is defined as described above, the second ratio in the state where the pressure detected by the master cylinder pressure sensor 41 of the rear wheel braking mechanism 14 is larger than P2 is the same as that of the master cylinder pressure sensor 41 of the rear wheel braking mechanism 14 The detected pressure is smaller than the second ratio in the state smaller than P2. That is, in the fourth mode D shown in FIG. 7, when the pressure detected by master cylinder pressure sensor 41 of rear wheel braking mechanism 14 becomes larger than P2, the pressure detected by master cylinder pressure sensor 41 of rear wheel braking mechanism 14 Is greater than P2, a large braking force is generated on the rear wheel 4.

  When it is desired to stop the motorcycle 100 suddenly, the amount of input to the rear brake operation unit 13 of the rider becomes large. By configuring the fourth mode D as shown in FIG. 7, when it is desired to stop the motorcycle 100 rapidly, the rear wheel 4 can be operated also in the fourth mode D which suppresses the temperature rise of the friction braking mechanism 29 of the rear wheel 4. Sufficient braking force can be generated to improve the safety of the motorcycle 100. Further, by configuring the fourth mode D as shown in FIG. 7, the friction braking mechanism 29 of the rear wheel 4 is at least in a state where the pressure detected by the master cylinder pressure sensor 41 of the rear wheel braking mechanism 14 is smaller than P2. It is possible to perform interlocking brake control that can be protected more than before.

  In the fourth mode D shown in FIG. 7, when the pressure detected by the master cylinder pressure sensor 41 of the rear wheel braking mechanism 14 is larger than P2, the braking force generated on the rear wheel 4 is the third. It is the same as the braking force generated on the rear wheel 4 in mode C. However, this is just an example. When the pressure detected by the master cylinder pressure sensor 41 of the rear wheel braking mechanism 14 is larger than P2, the braking force generated on the rear wheel 4 in the fourth mode D is applied to the rear wheel 4 in the third mode C. It may be smaller than the generated braking force.

  Here, in the fourth mode D, the braking force of the rear wheel 4 is reduced compared to the third mode C. Therefore, when the third mode C or the fourth mode D is selected during the second interlocking brake control, the braking force generated on the front wheel 3 may be controlled as follows.

  FIG. 8 is an explanatory view showing an example of the braking force generated on the front wheels in the third mode and the fourth mode selected by the mode selection unit of the control device according to the embodiment of the present invention at the time of second interlocking brake control. . The RMP shown on the horizontal axis of FIG. 8 is the same as that of FIG. 6 and is the hydraulic pressure of the brake fluid of the master cylinder 21 detected by the master cylinder pressure sensor 41 of the rear wheel braking mechanism 14. That is, the horizontal axis in FIG. 8 indicates the amount of input to the rear brake operation unit 13 of the rider. Further, FWP shown on the vertical axis of FIG. 8 is an abbreviation of Front Wheel Pressure, which is the hydraulic pressure of the brake fluid of the wheel cylinder 24 detected by the wheel cylinder pressure sensor 42 of the front wheel braking mechanism 12. That is, the vertical axis in FIG. 8 indicates the braking force generated on the front wheel 3. Further, the broken line shown in FIG. 8 indicates the third mode C, and the solid line shown in FIG. 8 indicates the fourth mode D.

  Specifically, when the braking force generated on the front wheel 3 in the third mode C is compared with the braking force generated on the front wheel 3 in the fourth mode D under the same condition as the input amount to the rear brake operating unit 13, The braking force generated on the front wheel 3 in the fourth mode D may be larger than the braking force generated on the front wheel 3 in the third mode C.

  By controlling the braking force generated on the front wheel 3 in this manner, the braking force of the entire motorcycle 100, which is the sum of the braking force of the front wheel 3 and the braking force of the rear wheel 4, can be compared with the third mode C and the fourth mode D. For example, it can be made substantially the same. Therefore, by controlling the braking force generated on the front wheel 3 in this manner, the braking distance of the motorcycle 100 in the fourth mode D can be prevented from being longer than the third mode C. The magnitude of the braking force generated on the front wheel 3 at the time of the second interlocking brake control is, for example, the number of revolutions of the drive source (motor or the like) of the pump 34 of the front wheel braking mechanism 12 and the opening of the loading valve 31 of the front wheel braking mechanism 12 The adjustment can be made by controlling at least one of the angle and the opening time of the loading valve 31 of the front wheel braking mechanism 12.

  The braking force generated on the front wheel 3 in the third mode C and the fourth mode D may be controlled as follows.

  FIG. 9 is an explanatory view showing another example of the braking force generated on the front wheels in the third mode and the fourth mode selected by the mode selection unit of the control device according to the embodiment of the present invention at the time of second interlocking brake control. It is. The horizontal and vertical axes in FIG. 9 are the same as in FIG.

  The ratio of the braking force generated on the front wheel 3 in the fourth mode D to the braking force generated on the front wheel 3 in the third mode C under the same condition as the amount of input to the rear brake operating unit 13 is defined as the front wheel ratio. For example, a certain input amount to the rear brake operation unit 13 is set as a detected pressure P of the master cylinder pressure sensor 41 of the rear wheel braking mechanism 14. When the input amount to the rear brake operation unit 13 is P in the fourth mode D, the fluid pressure of the brake fluid of the wheel cylinder 24 detected by the wheel cylinder pressure sensor 42 of the front wheel braking mechanism 12 is PD. When the input amount to the rear brake operation unit 13 is P in the third mode C, the hydraulic pressure of the brake fluid of the wheel cylinder 24 detected by the wheel cylinder pressure sensor 42 of the front wheel braking mechanism 12 is PC. In this case, the front wheel ratio when the input amount to the rear brake operation unit 13 is P is a value obtained by dividing PD by PC. That is, the front wheel ratio when the input amount to the rear brake operation unit 13 is P is PD / PC. That is, in the third mode C, the reduction amount of the braking force generated on the front wheel 3 with respect to the fourth mode D decreases as the front wheel ratio decreases.

  When the front wheel ratio is defined as described above, the front wheel ratio in the state where the detected pressure of the master cylinder pressure sensor 41 of the rear wheel braking mechanism 14 is larger than P2 is the detected pressure of the master cylinder pressure sensor 41 of the rear wheel braking mechanism 14 Is smaller than the front wheel ratio in the state smaller than P2. That is, in the third mode C shown in FIG. 9, when the pressure detected by master cylinder pressure sensor 41 of rear wheel braking mechanism 14 becomes larger than P2, the pressure detected by master cylinder pressure sensor 41 of rear wheel braking mechanism 14 Is greater than P2, a large braking force is generated on the front wheel 3.

  By configuring the third mode C as shown in FIG. 9, the braking force of the motor cycle 100 can be improved in a state where it is desired to stop the motor cycle 100 rapidly, and the safety of the motor cycle 100 is improved.

  In the third mode C shown in FIG. 9, when the pressure detected by the master cylinder pressure sensor 41 of the rear wheel braking mechanism 14 is larger than P2, the braking force generated on the front wheel 3 is the fourth mode. It is the same as the braking force generated on the front wheel 3 at D. However, this is just an example. When the pressure detected by the master cylinder pressure sensor 41 of the rear wheel braking mechanism 14 is larger than P2, the braking force generated on the front wheel 3 in the third mode C is generated on the front wheel 3 in the fourth mode D It may be smaller than the braking force.

  By the way, as mentioned above, in the conventional interlocking brake control, the braking force is always generated on both the front wheel and the rear wheel. For this reason, in the conventional interlocking brake control, the temperature of the friction braking mechanism 29 of the front wheel also easily rises. Therefore, the mode selection unit 62 of the control device 60 of the motorcycle 100 according to the present embodiment suppresses the temperature rise of the friction braking mechanism 29 of the front wheel 3 during the second interlocking brake control, compared to the conventional case. E or sixth mode F is selected.

  FIG. 10 is an explanatory view showing an example of the braking force generated on the front wheels in the fifth mode and the sixth mode selected by the mode selection unit of the control device according to the embodiment of the present invention at the time of second interlocking brake control. . The RMP shown on the horizontal axis in FIG. 10 is the hydraulic pressure of the brake fluid of the master cylinder 21 detected by the master cylinder pressure sensor 41 of the rear wheel braking mechanism 14 as in FIG. That is, the horizontal axis in FIG. 10 indicates the amount of input to the rear brake operation unit 13 of the rider. Further, FWP shown on the vertical axis of FIG. 10 is the hydraulic pressure of the brake fluid of the wheel cylinder 24 detected by the wheel cylinder pressure sensor 42 of the front wheel braking mechanism 12 as in FIG. That is, the vertical axis in FIG. 10 indicates the braking force generated on the front wheel 3. Further, the broken line shown in FIG. 10 indicates the fifth mode E, and the solid line shown in FIG. 10 indicates the sixth mode F.

  Specifically, the mode selection unit 62 selects the fifth mode E when the temperature of the friction braking mechanism 29 of the front wheel 3 is lower than the third specified temperature at the time of the second interlocking brake control. Further, the mode selection unit 62 selects the sixth mode F when the temperature of the friction braking mechanism 29 of the front wheel 3 is higher than the third specified temperature at the time of the second interlocking brake control. Then, when the braking force generated on the front wheel 3 in the fifth mode E is compared with the braking force generated on the front wheel 3 in the sixth mode F under the same condition as the input amount to the rear brake operation unit 13, the sixth The braking force generated on the front wheel 3 in mode F is smaller than the braking force generated on the front wheel 3 in the fifth mode E.

  At the time of the second interlocking brake control, the mode selection unit 62 selects the fifth mode E or the sixth mode F as described above, so that the temperature of the friction braking mechanism 29 of the front wheel 3 is higher than the third prescribed temperature. When it becomes, the braking force generated on the front wheel 3 can be reduced. That is, by selecting the sixth mode F, the temperature rise of the friction braking mechanism 29 of the front wheel 3 can be suppressed. For this reason, at the time of the second interlocking brake control, the mode selection unit 62 selects the fifth mode E or the sixth mode F as described above, thereby suppressing the temperature rise of the friction braking mechanism 29 of the front wheel 3 more than before. be able to. Therefore, at the time of the second interlocking brake control, the interlocking brake control capable of protecting the friction braking mechanism 29 of the front wheel 3 more than before by selecting the fifth mode E or the sixth mode F as described above. It can be carried out.

  In FIG. 10, the brake force is not generated on the front wheel 3 in the sixth mode F. However, the sixth mode F shown in FIG. 10 is merely an example. For example, in the sixth mode F, the braking force may be generated on the front wheel 3. That is, when the braking force generated on the front wheel 3 in the fifth mode E is compared with the braking force generated on the front wheel 3 in the sixth mode F under the same condition as the input amount to the rear brake operation unit 13, the sixth The braking force generated on the front wheel 3 in mode F may be smaller than the braking force generated on the front wheel 3 in the fifth mode E. Also, for example, the sixth mode F may be configured as follows.

  FIG. 11 is an explanatory view showing another example of the braking force generated on the front wheels in the fifth mode and the sixth mode selected by the mode selection unit of the control device according to the embodiment of the present invention at the time of second interlocking brake control. It is. The horizontal and vertical axes in FIG. 11 are the same as in FIG. Further, the pressure P3 detected by the master cylinder pressure sensor 41 of the rear wheel braking mechanism 14 that indicates the amount of input to the rear brake operation unit 13 corresponds to the third specified amount of the present invention.

  A ratio of the braking force generated on the front wheel 3 in the fifth mode E to the braking force generated on the front wheel 3 in the sixth mode F under the same condition as the amount of input to the rear brake operating unit 13 is defined as a third ratio. For example, a certain input amount to the rear brake operation unit 13 is set as a detected pressure P of the master cylinder pressure sensor 41 of the rear wheel braking mechanism 14. When the input amount to the rear brake operation unit 13 is P in the sixth mode F, it is assumed that the fluid pressure of the brake fluid of the wheel cylinder 24 detected by the wheel cylinder pressure sensor 42 of the front wheel braking mechanism 12 is PF. In the fifth mode E, when the input amount to the rear brake operation unit 13 is P, it is assumed that the hydraulic pressure of the brake fluid of the wheel cylinder 24 detected by the wheel cylinder pressure sensor 42 of the front wheel braking mechanism 12 is PE. In this case, the third ratio when the input amount to the rear brake operating unit 13 is P is a value obtained by dividing PE by PF. That is, the third ratio when the input amount to the rear brake operation unit 13 is P is PE / PF. That is, in the sixth mode F, the reduction amount of the braking force generated on the front wheel 3 with respect to the fifth mode E decreases as the third ratio decreases.

  When the third ratio is defined as described above, the third ratio in the state where the pressure detected by the master cylinder pressure sensor 41 of the rear wheel braking mechanism 14 is larger than P3 corresponds to that of the master cylinder pressure sensor 41 of the rear wheel braking mechanism 14 The detected pressure is smaller than the third ratio in the state smaller than P3. That is, in the sixth mode F shown in FIG. 11, when the pressure detected by master cylinder pressure sensor 41 of rear wheel braking mechanism 14 becomes larger than P3, the pressure detected by master cylinder pressure sensor 41 of rear wheel braking mechanism 14 Is greater than P3, a large braking force is generated on the front wheel 3.

  When it is desired to stop the motorcycle 100 suddenly, the amount of input to the rear brake operation unit 13 of the rider becomes large. By configuring the sixth mode F as shown in FIG. 11, when it is desired to stop the motorcycle 100 suddenly, the front wheel 3 is sufficient even in the sixth mode F which suppresses the temperature rise of the friction braking mechanism 29 of the front wheel 3. The braking force can be generated to improve the safety of the motorcycle 100. Further, by configuring the sixth mode F as shown in FIG. 11, the friction braking mechanism 29 of the front wheel 3 can be configured as in the prior art at least when the pressure detected by the master cylinder pressure sensor 41 of the rear wheel braking mechanism 14 is smaller than P3. It is possible to perform interlocking brake control that can be more protected.

  In the sixth mode F shown in FIG. 11, when the pressure detected by the master cylinder pressure sensor 41 of the rear wheel braking mechanism 14 is larger than P3, the braking force generated on the front wheel 3 is the fifth mode. It is the same as the braking force generated on the front wheel 3 at E. However, this is just an example. When the pressure detected by the master cylinder pressure sensor 41 of the rear wheel braking mechanism 14 is larger than P3, the braking force generated on the front wheel 3 in the sixth mode F is generated on the front wheel 3 in the fifth mode E It may be smaller than the braking force.

<Operation of control device>
Subsequently, an operation of the control device 60 at the time of interlocking brake control will be described. In the following, first, the operation of the control device 60 at the time of the first interlocking brake control will be described. And after that, operation | movement of the control apparatus 60 at the time of 2nd interlocking | linkage brake control is demonstrated.

FIG. 12 is a flowchart showing an operation at the time of the first interlocking brake control of the control device according to the embodiment of the present invention.
In a state where the interlocking brake control mode is selected by the mode selection unit 62, when the front brake operation unit 11 is operated in step S1, the control device 60 proceeds to step S2.

  Steps S2, S3 and S4 are mode selection steps for selecting the first mode A or the second mode B. In the mode selection step, the first mode A is selected when the temperature of the friction braking mechanism 29 of the rear wheel 4 is lower than the first specified temperature, and the temperature of the friction braking mechanism 29 of the rear wheel 4 is higher than the first specified temperature. In the high state, the second mode B is selected. Specifically, in step S2, the mode selection unit 62 compares the temperature of the friction braking mechanism 29 of the rear wheel 4 acquired by the temperature acquisition unit 61 with the first prescribed temperature. Then, if the temperature of the friction braking mechanism 29 of the rear wheel 4 is lower than the first specified temperature, the mode selection unit 62 proceeds to step S3 and selects the first mode A. If the temperature of the friction braking mechanism 29 of the rear wheel 4 is higher than the first specified temperature, the mode selection unit 62 proceeds to step S4 and selects the second mode B. If the temperature of the friction braking mechanism 29 of the rear wheel 4 is the same as the first specified temperature, the process may proceed to step S3 or may proceed to step S4.

  The process proceeds from step S2 to step S3. When the first mode A is selected, the process proceeds to step S5. In step S5, the mode selection unit 62 obtains the braking force of the rear wheel 4 generated as the input amount in the first mode A from the input amount to the front brake operation unit 11. Further, the mode selection unit 62 obtains the braking force of the rear wheel 4 generated by the input amount in the normal brake control mode from the input amount to the rear brake operation unit 13. Then, the mode selection unit 62 compares the braking force of the rear wheel 4 generated in the first mode A with the braking force of the rear wheel 4 generated in the normal brake control mode. If the braking force of the rear wheel 4 generated in the first mode A is equal to or greater than the braking force of the rear wheel 4 generated in the normal brake control mode, the mode selecting unit 62 proceeds to step S7 while selecting the first mode A. . On the other hand, when the braking force of the rear wheel 4 generated in the first mode A is smaller than the braking force of the rear wheel 4 generated in the normal brake control mode, the mode selection unit 62 sets the brake control mode to normal braking. It changes to the control mode and proceeds to step S9.

  Step S7 is a control step of controlling the braking force generated on the front wheel 3 and the braking force generated on the rear wheel 4 based on the mode selected in the mode selection step. That is, step S7 is a control step of controlling the braking force generated on the front wheel 3 and the braking force generated on the rear wheel 4 based on the first mode A. Specifically, in step S7, the control unit 63 controls the loading valve 31 and the relief valve of the front wheel braking mechanism 12 so that the braking force generated on the front wheel 3 becomes the braking force corresponding to the input amount of the front brake operating unit 11. 32 and the first valve 35 and the second valve 36 are controlled. Further, the control unit 63 controls the loading of the rear wheel braking mechanism 14 so that the braking force is generated on the rear wheel 4 in the first mode A according to the input amount of the front brake operation unit 11. The valve 31, the relief valve 32, the first valve 35, the second valve 36 and the pump 34 are controlled.

  In contrast to step S7, in step S9, the braking force generated on the front wheel 3 and the braking force generated on the rear wheel 4 in the normal brake control mode are controlled. Specifically, the control unit 63 causes the loading valve 31 and the relief valve 32 of the front wheel braking mechanism 12 to become the braking force corresponding to the input amount of the front brake operating unit 11 as the braking force generated on the front wheel 3 becomes the braking force. The valve 35 and the second valve 36 are controlled. Further, the control unit 63 causes the loading valve 31 of the rear wheel braking mechanism 14, the slackening valve 32, and so on so that the braking force generated on the rear wheel 4 becomes the braking force corresponding to the input amount of the rear brake operating unit 13. The first valve 35 and the second valve 36 are controlled.

  On the other hand, when the second mode B is selected by proceeding from step S2 to step S4, the mode selection unit 62 proceeds to step S6. In step S6, the mode selection unit 62 obtains the braking force of the rear wheel 4 generated in the second mode B from the input amount to the front brake operation unit 11. Further, the mode selection unit 62 obtains the braking force of the rear wheel 4 generated by the input amount in the normal brake control mode from the input amount to the rear brake operation unit 13. Then, the mode selection unit 62 compares the braking force of the rear wheel 4 generated in the second mode B with the braking force of the rear wheel 4 generated in the normal brake control mode. If the braking force of the rear wheel 4 generated in the second mode B is equal to or greater than the braking force of the rear wheel 4 generated in the normal brake control mode, the mode selecting unit 62 proceeds to step S8 while selecting the second mode B. . On the other hand, when the braking force of the rear wheel 4 generated in the second mode B is smaller than the braking force of the rear wheel 4 generated in the normal brake control mode, the mode selection unit 62 sets the control mode of the brake to the normal brake control mode. Change and go to step S9.

  Step S8 is a control step of controlling the braking force generated on the front wheel 3 and the braking force generated on the rear wheel 4 based on the mode selected in the mode selection step. That is, step S8 is a control step of controlling the braking force generated on the front wheel 3 and the braking force generated on the rear wheel 4 based on the second mode B. Specifically, in step S8, the control unit 63 controls the loading valve 31 and the relief valve of the front wheel braking mechanism 12 so that the braking force generated on the front wheel 3 becomes the braking force corresponding to the input amount of the front brake operating unit 11. 32 and the first valve 35 and the second valve 36 are controlled. Further, the control unit 63 controls the loading of the rear wheel braking mechanism 14 so that the braking force is generated on the rear wheel 4 in the second mode B according to the input amount of the front brake operating unit 11. The valve 31, the relief valve 32, the first valve 35, the second valve 36 and the pump 34 are controlled.

  After step S7, step S8 or step S9, the control device 60 proceeds to step S10. Then, in step S10, the control device 60 determines whether or not the operation of the front brake operation unit 11 is released. When the operation of the front brake operating unit 11 is not released, that is, when the front brake operating unit 11 is in the operated state, the control device 60 returns to step S2. When the operation of the front brake operation unit 11 is released, the control device 60 proceeds to step S11 and ends the control of causing the front wheel 3 and the rear wheel 4 to generate a braking force.

FIG. 13 is a flowchart showing an operation at the time of the second interlocking brake control of the control device according to the embodiment of the present invention.
In a state where the interlocking brake control mode is selected by the mode selection unit 62, when the rear brake operation unit 13 is operated in step S21, the control device 60 proceeds to step S22.

  Steps S22, S31 and S41 are mode selection steps for selecting the third mode C or the fourth mode D. In these mode selection steps, the third mode C is selected when the temperature of the friction braking mechanism 29 of the rear wheel 4 is lower than the second specified temperature, and the temperature of the friction braking mechanism 29 of the rear wheel 4 is the second specified. The fourth mode D is selected in the state higher than the temperature. Specifically, in step S22, the mode selection unit 62 compares the temperature of the friction braking mechanism 29 of the rear wheel 4 acquired by the temperature acquisition unit 61 with the second specified temperature. Then, if the temperature of the friction braking mechanism 29 of the rear wheel 4 is lower than the second specified temperature, the mode selection unit 62 proceeds to step S31 and selects the third mode C. When the temperature of the friction braking mechanism 29 of the rear wheel 4 is higher than the second specified temperature, the mode selection unit 62 proceeds to step S41 and selects the fourth mode D. If the temperature of the friction braking mechanism 29 of the rear wheel 4 is the same as the second prescribed temperature, the process may proceed to step S31 or may proceed to step S41.

  Steps S32, S33, and S34 after the third mode C is selected in step S31 are mode selection steps for selecting the fifth mode E or the sixth mode F. In these mode selection steps, the fifth mode E is selected when the temperature of the friction braking mechanism 29 of the front wheel 3 is lower than the third specified temperature, and the temperature of the friction braking mechanism 29 of the front wheel 3 is higher than the third specified temperature. In the high state, the sixth mode F is selected. Specifically, in step S32, the mode selection unit 62 compares the temperature of the friction braking mechanism 29 of the front wheel 3 acquired by the temperature acquisition unit 61 with the third prescribed temperature. Then, if the temperature of the friction braking mechanism 29 of the front wheel 3 is lower than the third specified temperature, the mode selection unit 62 proceeds to step S33 and selects the fifth mode E. When the temperature of the friction braking mechanism 29 of the front wheel 3 is higher than the third specified temperature, the mode selection unit 62 proceeds to step S34 and selects the sixth mode F. When the temperature of the friction braking mechanism 29 of the front wheel 3 is the same as the third specified temperature, the process may proceed to step S33 or may proceed to step S34.

  When the fifth mode E is selected by proceeding from step S32 to step S33, the mode selection unit 62 proceeds to step S35. In step S35, the mode selection unit 62 obtains the braking force of the front wheel 3 generated with the input amount in the fifth mode E from the input amount to the rear brake operation unit 13. Further, the mode selection unit 62 obtains the braking force of the front wheel 3 generated by the input amount in the normal brake control mode from the input amount to the front brake operation unit 11. Then, the mode selection unit 62 compares the braking force of the front wheel 3 generated in the fifth mode E with the braking force of the front wheel 3 generated in the normal brake control mode. If the braking force of the front wheel 3 generated in the fifth mode E is equal to or greater than the braking force of the front wheel 3 generated in the normal brake control mode, the mode selecting unit 62 proceeds to step S37 while selecting the fifth mode E. On the other hand, when the braking force of the front wheel 3 generated in the fifth mode E is smaller than the braking force of the front wheel 3 generated in the normal brake control mode, the mode selection unit 62 sets the brake control mode to the normal brake control mode. And go to step S39.

  Step S37 is a control step of controlling the braking force generated on the front wheel 3 and the braking force generated on the rear wheel 4 based on the mode selected in the mode selection step. That is, step S37 is a control step of controlling the braking force generated on the front wheel 3 and the braking force generated on the rear wheel 4 based on the third mode C and the fifth mode E. Specifically, in step S37, the control unit 63 controls the front wheel braking mechanism so that the braking force is generated on the front wheel 3 at the time of the input amount in the fifth mode E according to the input amount of the rear brake operation unit 13. The 12 loading valves 31, the loosening valve 32, the first valve 35, the second valve 36 and the pump 34 are controlled. Further, the control unit 63 controls the loading of the rear wheel braking mechanism 14 so that the braking force is generated on the rear wheel 4 in the third mode C in accordance with the input amount of the rear brake operation unit 13. The valve 31, the relief valve 32, the first valve 35, and the second valve 36 are controlled. In contrast to step S37, in step S39, the braking force generated on the front wheel 3 and the braking force generated on the rear wheel 4 in the normal brake control mode are controlled. This control is the same as step S9 in FIG.

  If the sixth mode F is selected by proceeding from step S32 to step S34, the mode selection unit 62 proceeds to step S36. In step S36, the mode selection unit 62 obtains the braking force of the front wheel 3 generated with the input amount in the sixth mode F from the input amount to the rear brake operation unit 13. Further, the mode selection unit 62 obtains the braking force of the front wheel 3 generated by the input amount in the normal brake control mode from the input amount to the front brake operation unit 11. Then, the mode selection unit 62 compares the braking force of the front wheel 3 generated in the sixth mode F with the braking force of the front wheel 3 generated in the normal brake control mode. If the braking force of the front wheel 3 generated in the sixth mode F is equal to or greater than the braking force of the front wheel 3 generated in the normal brake control mode, the mode selecting unit 62 proceeds to step S38 while selecting the sixth mode F. On the other hand, when the braking force of the front wheel 3 generated in the sixth mode F is smaller than the braking force of the front wheel 3 generated in the normal brake control mode, the mode selection unit 62 changes the control mode of the brake to the normal brake control mode. , And proceeds to step S39.

  Step S38 is a control step of controlling the braking force generated on the front wheel 3 and the braking force generated on the rear wheel 4 based on the mode selected in the mode selection step. That is, step S38 is a control step of controlling the braking force generated on the front wheel 3 and the braking force generated on the rear wheel 4 based on the third mode C and the sixth mode F. Specifically, in step S38, the control unit 63 controls the front wheel braking mechanism so that the braking force is generated on the front wheel 3 at the time of the input amount in the sixth mode F according to the input amount of the rear brake operating unit 13. The 12 loading valves 31, the loosening valve 32, the first valve 35, the second valve 36 and the pump 34 are controlled. Further, the control unit 63 controls the loading of the rear wheel braking mechanism 14 so that the braking force is generated on the rear wheel 4 in the third mode C in accordance with the input amount of the rear brake operation unit 13. The valve 31, the relief valve 32, the first valve 35, and the second valve 36 are controlled.

  On the other hand, step S42, step S43 and step S44 after the fourth mode D is selected in step S41 are the same as step S32, step S33 and step S34 described above, either fifth mode E or sixth mode F. It is a mode selection step to select. In these mode selection steps, if the temperature of the friction braking mechanism 29 of the front wheel 3 is lower than the third specified temperature, the mode selection unit 62 proceeds to step S43 and selects the fifth mode E. When the temperature of the friction braking mechanism 29 of the front wheel 3 is higher than the third specified temperature, the mode selection unit 62 proceeds to step S44 and selects the sixth mode F. When the temperature of the friction braking mechanism 29 of the front wheel 3 is the same as the third specified temperature, the process may proceed to step S43 or may proceed to step S44.

  When the fifth mode E is selected by proceeding from step S42 to step S43, the mode selection unit 62 proceeds to step S45. In step S45, the mode selection unit 62 compares the braking force of the front wheel 3 generated in the fifth mode E with the braking force of the front wheel 3 generated in the normal brake control mode, as in step S35. If the braking force of the front wheel 3 generated in the fifth mode E is equal to or greater than the braking force of the front wheel 3 generated in the normal brake control mode, the mode selecting unit 62 proceeds to step S47 while selecting the fifth mode E. On the other hand, when the braking force of the front wheel 3 generated in the fifth mode E is smaller than the braking force of the front wheel 3 generated in the normal brake control mode, the mode selection unit 62 sets the brake control mode to the normal brake control mode. And the process proceeds to step S49.

  Step S47 is a control step of controlling the braking force generated on the front wheel 3 and the braking force generated on the rear wheel 4 based on the mode selected in the mode selection step. That is, step S47 is a control step of controlling the braking force generated on the front wheel 3 and the braking force generated on the rear wheel 4 based on the fourth mode D and the fifth mode E. Specifically, in step S47, the control unit 63 controls the front wheel braking mechanism so that the braking force is generated on the front wheel 3 at the time of the input amount in the fifth mode E according to the input amount of the rear brake operation unit 13. The 12 loading valves 31, the loosening valve 32, the first valve 35, the second valve 36 and the pump 34 are controlled. Further, the control unit 63 controls the loading of the rear wheel braking mechanism 14 so that the braking force is generated on the rear wheel 4 in the fourth mode D in accordance with the input amount of the rear brake operating unit 13. The valve 31, the relief valve 32, the first valve 35, and the second valve 36 are controlled. In contrast to step S47, in step S49, the braking force generated on the front wheel 3 and the braking force generated on the rear wheel 4 in the normal brake control mode are controlled.

  When the sixth mode F is selected by proceeding from step S42 to step S44, the mode selection unit 62 proceeds to step S46. In step S46, as in step S36, the mode selection unit 62 compares the braking force of the front wheel 3 generated in the sixth mode F with the braking force of the front wheel 3 generated in the normal brake control mode. If the braking force of the front wheel 3 generated in the sixth mode F is equal to or greater than the braking force of the front wheel 3 generated in the normal brake control mode, the mode selecting unit 62 proceeds to step S48 while selecting the sixth mode F. On the other hand, when the braking force of the front wheel 3 generated in the sixth mode F is smaller than the braking force of the front wheel 3 generated in the normal brake control mode, the mode selection unit 62 changes the control mode of the brake to the normal brake control mode. , And proceeds to step S49.

  Step S48 is a control step of controlling the braking force generated on the front wheel 3 and the braking force generated on the rear wheel 4 based on the mode selected in the mode selection step. That is, step S48 is a control step of controlling the braking force generated on the front wheel 3 and the braking force generated on the rear wheel 4 based on the fourth mode D and the sixth mode F. Specifically, in step S48, the control unit 63 controls the front wheel braking mechanism so that the braking force is generated on the front wheel 3 at the time of the input amount in the sixth mode F in accordance with the input amount of the rear brake operating unit 13. The 12 loading valves 31, the loosening valve 32, the first valve 35, the second valve 36 and the pump 34 are controlled. Further, the control unit 63 controls the loading of the rear wheel braking mechanism 14 so that the braking force is generated on the rear wheel 4 in the fourth mode D in accordance with the input amount of the rear brake operating unit 13. The valve 31, the relief valve 32, the first valve 35, and the second valve 36 are controlled.

  After step S37, step S38, step S39, step S47, step S48 or step S49, the control device 60 proceeds to step S50. Then, in step S50, the control device 60 determines whether or not the operation of the rear brake operation unit 13 is released. When the operation of the rear brake operation unit 13 is not released, that is, when the rear brake operation unit 13 is in the operated state, the control device 60 returns to step S22. When the operation of the rear brake operation unit 13 is released, the control device 60 proceeds to step S51, and ends the control of causing the front wheel 3 and the rear wheel 4 to generate a braking force.

  In FIG. 13, at the time of the second interlocking brake control, the mode selection unit 62 selects the third mode C or the fourth mode D, and also selects the fifth mode E or the sixth mode F. However, this is just an example. For example, when it is only necessary to suppress the temperature rise of the friction braking mechanism 29 of the rear wheel 4, the mode selection unit 62 selects the third mode C or the fourth mode D at the time of the second interlocking brake control. It is not necessary to select the fifth mode E or the sixth mode F. Further, for example, when it is only necessary to suppress the temperature rise of the friction braking mechanism 29 of the front wheel 3, the mode selection unit 62 selects the fifth mode E or the sixth mode F at the time of the second interlocking brake control. It is not necessary to select the third mode C or the fourth mode D.

  As mentioned above, although embodiment was described, this invention is not limited to description of embodiment. For example, only a part of the embodiments may be implemented, and the order of the steps may be reversed.

Reference Signs List 1 body, 2 steering wheel, 3 front wheel, 3a rotor, 4 rear wheel, 4a rotor, 10 brake system, 11 front brake operating unit, 12 front wheel braking mechanism, 13 rear brake operating unit, 14 rear wheel braking mechanism, 21 master cylinder, Reference Signs List 22 reservoir, 23 brake caliper, 24 wheel cylinder, 25 brake pad, 26 main channel, 27 sub channel, 28 supply channel, 29 friction braking mechanism, 31 loading valve, 32 slack valve, 33 accumulator, 34 pump, 35 1st valve, 36 second valve, 41 master cylinder pressure sensor, 42 wheel cylinder pressure sensor, 43 front wheel rotational speed sensor, 44 rear wheel rotational speed sensor, 50 hydraulic control unit, 51 base, 60 controller, 61 temperature acquisition Part 62 mode selection part 63 control part 100 motor cycle A first mode B 2 mode, C third mode, D fourth mode, E fifth mode, F sixth mode.

Claims (9)

When the front brake operation unit (11) requesting the generation of the braking force to the front wheel (3) is operated, the braking force is generated to the front wheel (3) and the generation of the braking force to the rear wheel (4) is required A motorcycle control device (60) for performing a first interlocking brake control that causes the rear wheel (4) to generate a braking force even if the rear brake operation unit (13) is not operated,
When the temperature of the rear wheel friction braking mechanism which is the friction braking mechanism (29) of the rear wheel (4) is lower than the first specified temperature at the time of the first interlocking brake control, the first mode (A) is selected A mode selection unit (62) for selecting a second mode (B) when the temperature of the rear wheel friction braking mechanism is higher than the first specified temperature;
Under the same condition as the input amount to the front brake operation unit (11), the braking force generated on the rear wheel (4) in the first mode (A) and the rear wheel (in the second mode (B) When comparing with the braking force generated in 4),
The braking force generated on the rear wheel (4) in the second mode (B) is at least the state where the input amount to the front brake operating portion (11) is smaller than the first prescribed amount (P1). A control device (60) for a motorcycle (100) which is smaller than the braking force generated on the rear wheel (4) in the first mode (A). The rear wheel (4) in the first mode (A) with respect to the braking force generated on the rear wheel (4) in the second mode (B) under the condition that the input amount to the front brake operation unit (11) is the same When the ratio of the braking force generated in) is defined as the first ratio,
In the first ratio when the input amount to the front brake operation unit (11) is larger than the first predetermined amount (P1), the input amount to the front brake operation unit (11) is the first predetermined amount The control device (60) of the motor cycle (100) according to claim 1, wherein the first ratio is smaller than (P1). The control device (60) generates a braking force on the rear wheel (4) when the rear brake operating portion (13) is operated, and the front brake operating portion (11) is not operated. The control device (60) of a motor cycle (100) according to claim 1 or 2, wherein a second interlocking brake control is performed to generate a braking force on the front wheel (3). The mode selection unit (62) selects the third mode (C) when the temperature of the rear wheel friction braking mechanism is lower than the second specified temperature at the time of the second interlocking brake control, and the rear wheel friction is The fourth mode (D) is selected when the temperature of the braking mechanism is higher than the second specified temperature,
Under the same condition as the input amount to the rear brake operating portion (13), the braking force generated on the rear wheel (4) in the third mode (C) and the rear wheel (in the fourth mode (D) When comparing with the braking force generated in 4),
The braking force generated on the rear wheel (4) in the fourth mode (D) at least in the state where the input amount to the rear brake operating portion (13) is smaller than the second prescribed amount (P2) The control device (60) of the motor cycle (100) according to claim 3, wherein the control force (60) is smaller than the braking force generated on the rear wheel (4) in the third mode (C). The rear wheel (4) in the third mode (C) with respect to the braking force generated on the rear wheel (4) in the fourth mode (D) under the condition that the input amount to the rear brake operating portion (13) is the same If the ratio of the braking force generated in) is defined as the second ratio,
In the second ratio when the input amount to the rear brake operating portion (13) is larger than the second predetermined amount (P2), the input amount to the rear brake operating portion (13) is the second predetermined amount The control device (60) of the motorcycle (100) according to claim 4, wherein the second ratio is smaller than (P2). Furthermore,
The braking force generated on the front wheel (3) in the third mode (C) and the front wheel (3) in the fourth mode (D) under the same condition as the input amount to the rear brake operating portion (13) When comparing with the braking force generated in
The braking force generated on the front wheel (3) in the fourth mode (D) at least in the state where the input amount to the rear brake operating portion (13) is smaller than the second prescribed amount (P2) The control device (60) of the motor cycle (100) according to claim 4 or 5, wherein the braking force is greater than the braking force generated on the front wheel (3) in the third mode (C). The mode selection unit (62) is configured to control the temperature of the front wheel friction braking mechanism (29), which is the friction braking mechanism (29) of the front wheel (3), when the temperature of the front wheel friction braking mechanism (29) is lower Mode (E) is selected, and the sixth mode (F) is selected when the temperature of the front wheel friction braking mechanism is higher than the third specified temperature,
The braking force generated on the front wheel (3) in the fifth mode (E) and the front wheel (3) in the sixth mode (F) under the same condition as the input amount to the rear brake operating portion (13) When comparing with the braking force generated in
The brake force generated on the front wheel (3) in the sixth mode (F) is at least the state where the input amount to the rear brake operating portion (13) is smaller than the third prescribed amount (P3). The control device (60) of the motor cycle (100) according to any one of claims 3 to 6, wherein the control force (60) is smaller than the braking force generated on the front wheel (3) in the five modes (E). In the fifth mode (E) to the braking force generated on the front wheel (3) in the sixth mode (F) under the same condition as the input amount to the rear brake operating part (13) being in the fifth wheel (3) When the ratio of the generated braking force is defined as the third ratio,
In the third ratio when the input amount to the rear brake operating portion (13) is larger than the third predetermined amount (P3), the input amount to the rear brake operating portion (13) is the third predetermined amount The control device (60) of the motor cycle (100) according to claim 7, which is smaller than the third ratio in the state smaller than (P3). When the front brake operation unit (11) requesting the generation of the braking force to the front wheel (3) is operated, the braking force is generated to the front wheel (3) and the generation of the braking force to the rear wheel (4) is required And a control method of a motor cycle that performs interlocking brake control that causes the rear wheel (4) to generate a braking force even if the rear brake operation unit (13) is not operated.
When the temperature of the rear wheel friction braking mechanism which is the friction braking mechanism (29) of the rear wheel (4) is lower than the specified temperature at the time of the interlocking brake control, the first mode (A) is selected and the rear wheel Mode selection steps (S2, S3, S4) for selecting the second mode (B) when the temperature of the friction braking mechanism is higher than the prescribed temperature;
Control steps (S7, S8) for controlling the braking force generated on the front wheels and the braking force generated on the rear wheels based on the mode selected in the mode selection step;
Equipped with
Under the same condition as the input amount to the front brake operation unit (11), the braking force generated on the rear wheel (4) in the first mode (A) and the rear wheel (in the second mode (B) When comparing with the braking force generated in 4),
The braking force generated on the rear wheel (4) in the second mode (B) is at least the first when the input amount to the front brake operating portion (11) is smaller than the prescribed amount (P1). A control method of a motorcycle (100) smaller than a braking force generated on the rear wheel (4) in mode (A).

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