JP2019011057A - Bicycle device - Google Patents

Abstract

To provide a bicycle device which hardly grows in size even when mounted with an ABS unit.SOLUTION: A bicycle device comprises an ABS unit which is driven by an assist motor adding assist force to human drive force input through a clank shaft of a bicycle and controls braking force applied to a wheel of the bicycle. The ABS unit has a pump which applies hydraulic pressure to a braking device providing the wheel with braking force. The pump is driven by the assist motor.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a bicycle apparatus equipped with an ABS unit (Antilock Brake System).

  Bicycle apparatuses having an ABS unit are known. According to the bicycle device of Patent Document 1 as an example, the braking force applied to the bicycle wheel is controlled by the ABS unit.

International Publication No. 2014/108235

The bicycle apparatus is equipped with a drive source for driving the ABS unit. This increases the size of the bicycle device.
An object of the present invention is to provide a bicycle device that is difficult to increase in size even when an ABS unit is mounted.

  A bicycle apparatus according to a first aspect of the present disclosure includes an ABS unit that is driven by an assist motor that adds an assist force to a human-powered drive force input from a bicycle crankshaft and that controls a braking force applied to the bicycle wheel. The ABS unit includes a pump that applies hydraulic pressure to a braking device that applies braking force to the wheels, and the pump is driven by the assist motor.

  The bicycle apparatus according to the second aspect according to the first aspect of the present disclosure further includes the assist motor.

  In the bicycle apparatus according to the third aspect according to the first or second aspect of the present disclosure, an assist force is added to the human driving force by rotating the assist motor in a first direction, and the assist motor is The pump is driven by rotating in a second direction opposite to the direction of.

  In the bicycle apparatus according to the fourth aspect of the third aspect of the present disclosure, when the assist motor rotates in the first direction, no driving force is transmitted from the assist motor to the pump, and the assist motor And a one-way clutch that transmits a driving force from the assist motor to the pump when rotated in the direction of 2.

  The bicycle apparatus according to the fifth aspect according to any one of the first to fourth aspects of the present disclosure further includes a control device that controls the assist motor and the ABS unit.

  In the bicycle device according to the sixth aspect of the fifth aspect of the present disclosure, the control device detects a first detection device that detects an operation state of the operation device connected to the braking device, and detects a rotation state of the wheel. The assist motor and the ABS unit are controlled based on the detection result of the first detection device and the detection result of the second detection device.

  In the bicycle apparatus according to the seventh aspect according to the sixth aspect of the present disclosure, an assist force is added to the human power driving force by rotating the assist motor in a first direction, and the assist motor is moved in the first direction. When the pump is driven by rotating in the opposite second direction and the control device rotates the assist motor in the first direction, the assist motor is operated when the operation device is operated. Is reduced in the first direction.

  In the bicycle apparatus according to the eighth aspect according to the sixth or seventh aspect of the present disclosure, the control device is configured to provide a hydraulic pressure applied to the braking device based on a rotation state of the wheel when the operation device is operated. Is reduced by the ABS unit, and the assist motor is rotated in the second direction.

  In the bicycle apparatus according to the ninth aspect according to the eighth aspect of the present disclosure, when the control device rotates the assist motor in the second direction, the operation device is not operated. The rotation of the assist motor in the second direction is stopped.

  In the bicycle apparatus according to the tenth aspect according to the eighth or ninth aspect of the present disclosure, when the control device rotates the assist motor in the second direction, the rotation speed of the wheels is less than a predetermined speed. In this state, rotation of the assist motor in the second direction is stopped.

  In the bicycle apparatus according to the eleventh aspect according to any one of the eighth to tenth aspects of the present disclosure, the control device increases the hydraulic pressure by the pump after the hydraulic pressure applied to the braking device is reduced. .

  The bicycle apparatus according to the twelfth aspect according to any one of the first to eleventh aspects of the present disclosure further includes a housing provided with the assist motor and the ABS unit.

  In the bicycle apparatus according to the thirteenth aspect according to the twelfth aspect of the present disclosure, the pump of the ABS unit is provided in an internal space of the housing.

  In the bicycle apparatus according to the fourteenth aspect according to any one of the first to thirteenth aspects of the present disclosure, the wheel includes a front wheel and a rear wheel, and the ABS unit controls a braking force applied to the front wheel. 1 ABS unit and a second ABS unit for controlling the braking force applied to the rear wheel.

  According to the bicycle device of the present disclosure, it is difficult to increase the size even if the ABS unit is mounted.

The side view of the bicycle of a 1st embodiment. The block diagram of the bicycle of FIG. The flowchart of the control performed by the control apparatus of FIG. The flowchart of the control performed by the control apparatus of FIG. The block diagram of the bicycle of 2nd Embodiment. The block diagram of the bicycle of a modification.

(First embodiment)
FIG. 1 is an external view of an electrically assisted bicycle (hereinafter referred to as “bicycle 10”). The bicycle 10 includes a frame 12 that constitutes a main body thereof, front wheels 14 and rear wheels 16 that are rotatably attached to the frame 12, and a handle 18 that is operated to change the orientation of the front wheel 14. The bicycle 10 further includes a pair of brake levers 20F and 20R that are operating devices attached to the handle 18, a braking device 22F that applies a braking force to the front wheels 14, and a braking device 22R that applies a braking force to the rear wheels 16. The diameters of the front wheel 14 and the rear wheel 16 are substantially the same.

  Each brake device 22F, 22R is, for example, a disc brake. Each of the braking devices 22F and 22R includes disk rotors 26F and 26R fixed to the hubs 24F and 24R so as to be able to rotate integrally with the wheels, a pair of brake pads (not shown), and the brake pads as disk rotors 26F and 26R. Are provided with calipers 28F and 28R that brake the rotation of the disk rotors 26F and 26R.

  One brake lever 20F of the pair of brake levers 20F, 20R is connected to a caliper 28F for braking the front wheel 14. The other brake lever 20R is connected to a caliper 28R for braking the rear wheel 16. The calipers 28F and 28R sandwich the disc rotors 26F and 26R via the brake pads when the corresponding brake levers 20F and 20R are operated. Thereby, rotation of a wheel is braked.

  The brake levers 20F and 20R include a base portion 21A attached to the handle 18, a lever portion 21B rotatably connected to the base portion 21A, and a piston (not shown) connected to the lever portion 21B. When the brake levers 20F and 20R are operated, the lever portion 21B is displaced with respect to the base portion 21A from the initial position that is the position of the lever portion 21B when no force is applied.

  The bicycle 10 further includes a drive mechanism 30 that transmits a driving force to the rear wheels. The drive mechanism 30 includes a drive unit 32 that is detachably fixed to the frame 12 and a crankshaft 34 that is rotatably attached to the drive unit 32. The drive unit 32 includes an assist motor 36 that adds an assist force to the manpower driving force input from the crankshaft 34, and a housing 38 that houses a plurality of machine elements. The assist motor 36 is an electric motor and is provided in the housing 38. The assist motor 36 may be provided in the internal space of the housing 38. The bicycle 10 further includes a battery 40 that supplies power to the assist motor 36. The battery 40 is attached to the frame 12.

  The drive mechanism 30 further includes a pair of crank arms 42 connected to the crankshaft 34 and a pair of pedals 44 that are rotatably attached to the crank arms 42. The drive mechanism 30 is further attached to a front sprocket 48 connected to the crankshaft 34 via a one-way clutch 46 (see FIG. 2) and a rear wheel 16 hub 24R rotatably attached via a free wheel (not shown). A sprocket 50 and a chain 52 wound around the front sprocket 48 and the rear sprocket 50 are provided.

  When a manual driving force that causes the crank arm 42 to rotate forward is input to the pedal 44, the crank arm 42 and the crankshaft 34 integrally rotate forward with respect to the frame 12, and the rotation of the crankshaft 34 is transmitted to the front sprocket 48. Then, the rotation of the front sprocket 48 is transmitted to the rear sprocket 50 and the rear wheel 16 by the chain 52. On the other hand, when a manual driving force that rotates the crank arm 42 backward is input to the pedal 44 and the crank arm 42 and the crankshaft 34 rotate backward integrally with the frame 12, the one-way clutch 46 causes the crankshaft 34 to rotate. It is not transmitted to the front sprocket 48.

  The assist motor 36 rotates in the first direction in accordance with the manual driving force that rotates the crank arm 42 forward. When the assist motor 36 rotates in the first direction, the rotation of the assist motor 36 is transmitted to the front sprocket 48 via a speed reduction mechanism (not shown) and the one-way clutch 54 (see FIG. 2). For this reason, an assist force is added to the manpower driving force.

  FIG. 2 shows an electrical or mechanical connection relationship of the bicycle 10 (see FIG. 1). Note that the broken lines in FIG. 2 indicate the electrical connection relationship of the bicycle 10. Further, the solid line in FIG. 2 indicates the mechanical connection relationship of the bicycle 10.

  The bicycle 10 further includes a bicycle device 56 including a plurality of mechanical elements including the drive unit 32 (see FIG. 1). The bicycle device 56 is driven by the assist motor 36 and controls an ABS unit 58F that controls the braking force applied from the caliper 28F to the front wheel 14 (see FIG. 1), and a control device 60 that controls the assist motor 36 and the ABS unit 58F. Is provided. The ABS unit 58F is accommodated in the internal space of the housing 38.

  The ABS unit 58F includes a pump 62 that supplies hydraulic oil and applies hydraulic pressure to the caliper 28F, and a reservoir 64F that stores the hydraulic oil. The pump 62 is realized by, for example, a piston pump or a gear pump. Between the assist motor 36 and the pump 62, a one-way clutch 66 that is a component of the bicycle device 56 is disposed. The pump 62 is mechanically connected to the assist motor 36 via a one-way clutch 66.

  The one-way clutch 66 transmits the rotation of the assist motor 36 to the pump 62 when the output shaft of the assist motor 36 rotates in the second direction opposite to the first direction. For this reason, when the assist motor 36 rotates in the second direction, the pump 62 is driven via the one-way clutch 66. On the other hand, the one-way clutch 66 does not transmit the rotation of the assist motor 36 to the pump 62 when the output shaft of the assist motor 36 rotates in the first direction. The bicycle device 56 may further include a speed reduction mechanism (not shown) in the power transmission path between the assist motor 36 and the pump 62.

  The ABS unit 58F further includes a first valve 68F and a second valve 70F that adjust the hydraulic pressure applied to the caliper 28F. The first valve 68F is disposed in a pipe line that connects the brake lever 20F and the caliper 28F. The second valve 70F is disposed in a pipe line connecting the caliper 28F and the reservoir 64F.

  The first valve 68F and the second valve 70F are realized by electromagnetic valves or electric valves. When each valve 68F, 70F is realized by an electromagnetic valve, from the viewpoint of suppressing waste of electric power, an electromagnetic valve that is opened when no electric power is supplied is used as the first valve 68F, and no electric power is supplied. An electromagnetic valve that is sometimes closed is preferably used as the second valve 70F. The controller 60 controls the opening and closing of the valves 68F and 70F, thereby controlling the hydraulic pressure applied to the caliper 28F.

  When the hydraulic pressure applied to the caliper 28F is large, the caliper 28F is brought close to the disk rotor 26F (see FIG. 1). In this case, the caliper 28F sandwiches the disc rotor 26F via the brake pad, and the rotation of the front wheel 14 is braked. On the other hand, when the hydraulic pressure applied to the caliper 28F is small, the caliper 28F moves away from the disk rotor 26F. For this reason, the rotation of the front wheel 14 is not braked.

  The hydraulic fluid supplied from the pump 62 flows through the first pipeline 72F, the second pipeline 74F, and the third pipeline 76F. Each of the first pipeline 72F, the second pipeline 74F, and the third pipeline 76F is a pipeline branched into three. Each end of the first pipe line 72F is connected to the brake lever 20F, the pump 62, and the first valve 68F. Each end of the second pipe line 74F is connected to the caliper 28F, the first valve 68F, and the second valve 70F. Each end of the third conduit 76F is connected to the pump 62, the reservoir 64F, and the second valve 70F.

  The ABS unit 58F further includes a first check valve 78F disposed in the first pipeline 72F and a second check valve 80F disposed in the third pipeline 76F. The first check valve 78F has a role of flowing hydraulic oil from the pump 62 to the brake lever 20F side and not flowing hydraulic oil to the opposite side. The second check valve 80F has a role of flowing hydraulic oil from the reservoir 64F side to the pump 62 side and not flowing hydraulic oil to the opposite side. For this reason, when the pump 62 is driven, the hydraulic oil is supplied from the third pipeline 76F connected to the reservoir 64F to the first pipeline 72F. When the pump 62 is driven, the hydraulic pressure in the first pipeline 72F is increased. Further, when the second valve 70F is opened, the hydraulic oil flows from the second pipe line 74F to the third pipe line 76F through the second valve 70F as the pump 62 is driven.

  The bicycle 10 further detects a first detection device 82F that detects the operation state of the brake lever 20F, a second detection device 84F that detects the rotation state of the front wheel 14, and the rotation state of the rear wheel 16 (see FIG. 1). A second detection device 84R is provided. The first detection device 82F and the second detection devices 84F and 84R are electrically connected to the control device 60.

  The first detection device 82F is a sensor for detecting whether or not the lever portion 21B (see FIG. 1) of the brake lever 20F is operated by the user. The first detection device 82F is an angle sensor attached to the brake lever 20F, for example. The angle sensor is realized by, for example, a potentiometer, a magnetic sensor, an optical sensor, or the like. The first detection device 82F detects an operation state of the brake lever 20F by detecting an operation angle that is an angle of the lever portion 21B with respect to the base portion 21A (see FIG. 1). In addition, when an angle sensor is implement | achieved by the magnetic sensor, the magnetic sensor provided in 21 A of base parts detects the motion of the magnet provided in the lever part 21B.

  The second detection device 84F includes, for example, a magnetic sensor attached to the frame 12 (see FIG. 1) near the front wheel 14 and a magnet attached to the disk rotor 26F or the spoke of the front wheel 14. The second detection device 84F detects the rotation speed that is the rotation state of the front wheel 14 by the magnetic sensor detecting the magnet. A plurality of magnets that rotate together with the front wheel 14 may be provided in the circumferential direction of the front wheel 14, may be formed in an annular shape, and may be magnetized with different polarities alternately in the circumferential direction.

  The second detection device 84R includes, for example, a magnetic sensor attached to the frame 12 near the rear wheel 16, and a magnet attached to the disk rotor 26R or the spoke of the rear wheel 16. The second detection device 84 </ b> R detects the rotational speed that is the rotational state of the rear wheel 16 when the magnetic sensor detects the magnet. A plurality of magnets that rotate together with the rear wheel 16 may be provided in the circumferential direction of the rear wheel 16, may be formed in an annular shape, and may be magnetized with different polarities alternately in the circumferential direction.

  The control device 60 calculates the vehicle speed, which is the speed of the bicycle 10, based on the detection result of the rotational speed of at least one of the front wheels 14 and the rear wheels 16 detected by the second detection devices 84F and 84R. The control device 60 calculates the vehicle speed of the bicycle 10 based on the detection result with the high rotation speed among the detection results of the second detection devices 84F and 84R.

  The bicycle 10 further includes an operation unit 86 that is attached to the handle 18 (see FIG. 1) and that is operated to switch the operation mode of the assist motor 36, and a torque sensor 87 that detects human power driving force. The operation unit 86 and the torque sensor 87 are electrically connected to the control device 60. The torque sensor 87 is provided in a power transmission path between the crankshaft 34 and the front sprocket 48, for example. The torque sensor 87 is realized by, for example, a strain sensor or a magnetostrictive sensor.

  The operation unit 86 includes an assist selection switch (not shown) for selecting an operation mode of the assist motor 36. When the operation mode of the assist motor 36 is set to the assist-on mode by the assist selection switch, electric power is supplied from the battery 40 (see FIG. 1) to the assist motor 36 according to the detection result of the torque sensor 87. On the other hand, when the operation mode of the assist motor 36 is set to the assist-off mode by the assist selection switch, the human power driving force is not assisted by the assist motor 36.

  The operation unit 86 further includes an ABS operation changeover switch (not shown) for switching between an ABS operation mode in which the ABS unit 58F can be operated and an ABS non-operation mode in which the ABS unit 58F is not operated. The control of the ABS unit 58F by the control device 60 is executed by switching from the ABS non-operation mode to the ABS operation mode by the ABS operation switching switch. The control of the ABS unit 58F by the control device 60 does not depend on the operation of the assist selection switch.

  The control device 60 controls the output and rotation direction of the assist motor 36 based on the detection results of the first detection device 82F and the second detection devices 84F and 84R. The control device 60 includes a microprocessor and a memory, and operates when the microprocessor executes a program stored in the memory. Based on the detection results of the first detection device 82F and each of the second detection devices 84F and 84R, the control device 60 determines whether the first valve 68F and the second valve 70F are in the open / closed state by the first pattern and the second pattern. And switching to one of the third patterns. Table 1 shows the open / close state of the first valve 68F and the second valve 70F in each pattern.

The first pattern is a state in which the first valve 68F is opened and the second valve 70F is closed. The second pattern is a state in which the first valve 68F is closed and the second valve 70F is opened. The third pattern is a state in which both the first valve 68F and the second valve 70F are closed. When the operation unit 86 is set to the ABS non-operation mode, the first pattern is selected.

  When the first pattern is selected, when the brake lever 20F is operated, the piston of the brake lever 20F compresses the hydraulic oil in the first pipe line 72F and the second pipe line 74F. That is, the hydraulic pressure in the second pipe line 74F is increased, and the hydraulic pressure applied to the caliper 28F increases. Therefore, when the brake lever 20F is operated, the caliper 28F sandwiches the disk rotor 26F via the brake pad, and the rotation of the front wheel 14 is braked.

  When the second pattern is selected, the hydraulic oil in the second pipeline 74F moves into the third pipeline 76F, so the hydraulic pressure in the second pipeline 74F is reduced. For this reason, the hydraulic pressure applied to the caliper 28F is also reduced, and the braking force applied to the front wheels 14 is weakened. The hydraulic oil in the third pipe line 76F flows into the reservoir 64F and the pump 62. In the second pattern, since the first valve 68F is closed, even if the brake lever 20F is operated, the hydraulic pressure of the second pipe line 74F does not change. For this reason, the braking force applied to the front wheel 14 does not depend on the operation of the brake lever 20F.

  When the third pattern is selected, the hydraulic oil in the second pipeline 74F is held in the second pipeline 74F, so the hydraulic pressure in the second pipeline 74F is held. For this reason, the hydraulic pressure applied to the caliper 28F is also maintained, and the braking force applied to the front wheel 14 is maintained constant. In the third pattern, since the first valve 68F is closed, the braking force applied to the front wheel 14 does not depend on the operation of the brake lever 20F, as in the second pattern.

  3 and 4 are flowcharts of ABS operation control executed by the control device 60. FIG. The control device 60 starts the processing shown in FIGS. 3 and 4 when the operation unit 86 is set to the ABS operation mode. When the ABS operation mode has already been set, the processing shown in FIGS. 3 and 4 is started by turning on the power of the control device 60. The power source of the control device 60 is switched on and off by the operation unit 86. Here, a case where the assist-on mode is selected by the operation unit 86 will be described.

  The control device 60 rotates the assist motor 36 in the first direction according to the human driving force. The first pattern is maintained until the control device 60 switches the open / closed state of the valves 68F and 70F.

  In step S1, the control device 60 determines whether or not the brake lever 20F is operated based on the detection result of the first detection device 82F. If it is determined in step S1 that the brake lever 20F has not been operated, the process of step S1 is executed again. On the other hand, when it is determined in step S1 that the brake lever 20F is operated, the process of step S2 is executed. Note that when the ABS operation control is executed only on the front wheel 14 as in the first embodiment, only the brake lever 20F corresponding to the front wheel 14 is set as a detection target. On the other hand, when the ABS operation control is executed only on the rear wheel 16, only the brake lever 20R corresponding to the rear wheel 16 is set as a detection target.

  In step S <b> 2, the control device 60 reduces the output of the assist motor 36 when the assist motor 36 is rotated in the first direction according to the human power driving force. Then, the control device 60 finally stops the assist motor 36 by reducing the output of the assist motor 36.

  In step S3, the control device 60 determines whether or not the vehicle speed of the bicycle 10 is equal to or higher than a predetermined speed based on the detection results of the second detection devices 84F and 84R. The predetermined speed is preferably, for example, a speed of 5 km or less per hour. If it is determined in step S3 that the vehicle speed is equal to or higher than the predetermined speed, the process of step S4 is executed.

  In step S4, the control device 60 determines whether or not the state of the bicycle 10 is a predetermined state based on the detection results of the second detection devices 84F and 84R. The predetermined state is at least one of a state in which the difference between the rotational speed of the front wheel 14 and the rotational speed of the rear wheel 16 is equal to or greater than a predetermined speed, and a state in which a change in rotational speed of the wheel exceeds a predetermined value It is in the state.

  When the ABS operation control is executed only on the front wheel 14 as in the first embodiment, only the front wheel 14 is detected as to whether or not the change in the rotational speed of the wheel is greater than a predetermined value. On the other hand, when the ABS operation control is executed only on the rear wheel 16, only the rear wheel 16 is detected as to whether or not a change in rotational speed of a predetermined value or more has occurred on the wheel. When the predetermined state is established, it is suggested that the front wheel 14 to be braked by the operation of the brake lever 20F may be locked.

  If it is determined in step S4 that the state of the bicycle 10 is a predetermined state, the process of step S6 is executed. On the other hand, if it is determined in step S3 that the vehicle speed is less than the predetermined speed, or if it is determined in step S4 that the state of the bicycle 10 is not the predetermined state, the process of step S5 is executed.

  In step S5, the control device 60 returns the output of the assist motor 36 so that the assist motor 36 outputs a driving force corresponding to the human power driving force. That is, the control device 60 returns the output of the assist motor 36 forcibly decreased in step S2 to a state in which a driving force corresponding to the human power driving force is output. And the control apparatus 60 performs the process of step S1 again after finishing the process of step S5.

  In step S6, the control device 60 switches the open / close state of the first valve 68F and the second valve 70F from the first pattern to the second pattern. For this reason, the first valve 68F is closed and the second valve 70F is opened. For this reason, the hydraulic pressure applied to the caliper 28F is reduced, and the braking force applied to the front wheels 14 is weakened.

  In step S7, the control device 60 rotates the assist motor 36 in the second direction. When the assist motor 36 rotates in the second direction, a driving force is transmitted from the assist motor 36 to the pump 62, and the pump 62 is driven. For this reason, hydraulic fluid is supplied to the first pipeline 72F, and the hydraulic pressure of the first pipeline 72F starts to be increased. Note that, by increasing the hydraulic pressure of the first pipeline 72F, the lever portion 21B of the brake lever 20F is pushed back toward the initial position.

  In step S8, the control device 60 determines whether or not a predetermined time has elapsed since the execution of the process of step S6. If it is determined in step S8 that the predetermined time has not elapsed, the process of step S8 is executed again. On the other hand, if it is determined in step S8 that the predetermined time has elapsed, the process of step S9 is executed.

  In step S9, the control device 60 switches the open / close state of the first valve 68F and the second valve 70F from the second pattern to the third pattern. For this reason, both the first valve 68F and the second valve 70F are closed. For this reason, the hydraulic pressure applied to the caliper 28F is maintained, and the braking force applied to the front wheel 14 is maintained constant. Note that the hydraulic pressure applied to the caliper 28F continues to be reduced until the valves 68F and 70F are switched from the second pattern to the third pattern.

  In step S10, the control device 60 determines whether or not the brake lever 20F is operated based on the detection result of the first detection device 82F. In step S10, when it is determined that the brake lever 20F is operated, the process of step S11 is executed.

  In step S11, the control device 60 determines whether or not the vehicle speed of the bicycle 10 is equal to or higher than a predetermined speed based on the detection results of the second detection devices 84F and 84R. The predetermined speed is preferably, for example, a speed of 5 km or less per hour. If it is determined in step S11 that the vehicle speed is equal to or higher than the predetermined speed, the process of step S13 is executed. On the other hand, if it is determined in step S10 that the brake lever 20F is not operated, or if it is determined in step S11 that the vehicle speed is less than the predetermined speed, the process of step S12 is executed.

  In step S12, the control device 60 switches the open / close state of the first valve 68F and the second valve 70F from the third pattern to the first pattern. For this reason, the first valve 68F is opened and the second valve 70F is closed. For this reason, the rotation of the front wheel 14 is braked in conjunction with the operation of the brake lever 20F. And the control apparatus 60 performs the process of step S19, after finishing the process of step S12.

  In step S13, the control device 60 executes substantially the same process as the process executed in step S4. If it is determined in step S13 that the state of the bicycle 10 is a predetermined state, the process of step S14 is executed.

  In step S14, the control device 60 executes substantially the same process as the process executed in step S6. And the control apparatus 60 performs the process of step S8 again, after finishing the process of step S14. In addition, the control apparatus 60 determines whether predetermined time passed, after performing the process of step S14, when performing the process of step S8 through the process of step S14.

  On the other hand, if it is determined in step S13 that the state of the bicycle 10 is not a predetermined state, the process of step S15 is executed. In step S15, the control device 60 executes substantially the same process as the process executed in step S12.

  In step S16, the control device 60 determines whether or not the brake lever 20F is operated based on the detection result of the first detection device 82F. If it is determined in step S16 that the brake lever 20F is being operated, the process of step S17 is executed.

  In step S17, the control device 60 determines whether or not the vehicle speed of the bicycle 10 is equal to or higher than a predetermined speed based on the detection results of the second detection devices 84F and 84R. The predetermined speed is preferably, for example, a speed of 5 km or less per hour. If it is determined in step S17 that the vehicle speed is equal to or higher than the predetermined speed, the process of step S18 is executed. On the other hand, if it is determined in step S16 that the brake lever 20F is not operated, or if it is determined in step S17 that the vehicle speed is less than the predetermined speed, the process of step S19 is executed.

  In step S18, the control device 60 executes substantially the same process as the process executed in step S4. If it is determined in step S18 that the state of the bicycle 10 is the predetermined state, the process of step S14 is executed. On the other hand, if it is determined in step S18 that the state of the bicycle 10 is not a predetermined state, the process of step S19 is executed.

  In step S19, the control device 60 determines whether or not a predetermined time has elapsed after executing the process of step S6 or the process of step S14. Specifically, it is determined whether or not a predetermined time has elapsed since the last process in which the open / close state of the valves 68F and 70F has been switched to the second pattern. The predetermined time is determined in advance based on, for example, the time required to increase the amount of hydraulic oil in the first pipeline 72F and the second pipeline 74F to a predetermined amount. For example, the predetermined amount is substantially the same as that in the state before step S6.

  If it is determined in step S19 that the predetermined time has not elapsed, the process of step S19 is executed again. On the other hand, if it is determined in step S19 that the predetermined time has elapsed, the process of step S20 is executed.

  In step S20, the control device 60 stops the rotation of the assist motor 36 in the second direction. For this reason, the drive of the pump 62 stops. The control device 60 repeatedly executes the processes of step S1 to step S20 until the operation unit 86 switches from the ABS operation mode to the ABS non-operation mode. Note that, when the assist-off mode is selected by the operation unit 86, the ABS operation control in which the processes in steps S2 and S5 are omitted from the processes shown in FIGS. 3 and 4 is executed.

The operation of the bicycle device 56 will be described with reference to FIGS. 1 and 2.
The user operates the operation unit 86 before boarding the bicycle 10 or during traveling. When the assist-on mode is set by the operation unit 86, the assist motor 36 rotates in the first direction according to the manpower driving force input to the pedal 44, and the assist force is added to the manpower driving force.

  When the user operates the brake lever 20F when the vehicle speed is equal to or higher than the predetermined speed, the front wheel 14 may be locked depending on the road surface condition or the strength with which the user holds the brake lever 20F. At this time, the assist motor 36 and the ABS unit 58F are controlled by the control device 60, and the braking force applied to the front wheel 14 of the bicycle 10 is controlled. Specifically, when the operation unit 86 is set to the ABS operation mode, the processes in steps S1 to S20 shown in FIGS. 3 and 4 are repeatedly executed.

  For this reason, even if the front wheel 14 is likely to be locked due to the operation of the brake lever 20F, the ABS unit 58F is driven by the control device 60, and the front wheel 14 returns to the normal state. For this reason, it becomes difficult for the user to lose balance during traveling.

  The pump 62 of the ABS unit 58F is driven by the assist motor 36 rotating in the second direction. That is, the assist force is added to the human driving force by rotating the assist motor 36 in the first direction, and the pump 62 is driven by rotating the assist motor 36 in the second direction. For this reason, the assisting force is added to the human-powered driving force by the assist motor 36, and the bicycle device 56 is less likely to be larger than the configuration in which the pump 62 is driven by a drive source different from the assist motor 36. For this reason, the bicycle 10 can be reduced in size and weight.

According to the bicycle device 56 of the first embodiment, the following effects can be further obtained.
(1) When the brake lever 20F is operated while the assist motor 36 is rotating in the first direction, the bicycle device 56 causes the control device 60 to reduce the output of the assist motor 36. For this reason, when the front wheel 14 is likely to be locked in accordance with the operation of the brake lever 20F, the output of the assist motor 36 is small, so that it is difficult for the user to lose balance during traveling.

  (2) The bicycle device 56 controls the assist motor 36 and the ABS unit 58F by the control device 60, thereby reducing the hydraulic pressure applied to the caliper 28F and rotating the assist motor 36 in the second direction. Then, the pump 62 is driven. For this reason, compared with the configuration in which the pump 62 is driven after reducing the hydraulic pressure applied to the caliper 28F, the amount of hydraulic oil flowing through the first pipeline 72F and the second pipeline 74F is reduced to a predetermined amount earlier. Easy to rise.

  (3) When the rotation speed of the wheel of the bicycle 10 is less than the predetermined speed, that is, when the vehicle speed of the bicycle 10 is less than the predetermined speed, even if the wheel is locked, it is difficult for the user to lose balance during traveling. Based on this point, the bicycle device 56 does not drive the ABS unit 58F or stops the driving of the ABS unit 58F when the control device 60 determines that the vehicle speed is lower than the predetermined speed. For this reason, even when the vehicle speed is less than the predetermined speed, waste of electric power can be suppressed as compared with the configuration in which the ABS unit 58F is driven or the configuration in which the ABS unit 58F is continuously driven.

  (4) The bicycle device 56 accommodates the assist motor 36 and the ABS unit 58F in the internal space of the housing 38. For this reason, compared with the structure in which a part or all of the ABS unit 58F is provided outside the housing 38, the ABS unit 58F can be protected.

  (5) According to the bicycle 10, the hydraulic pressure applied to the caliper 28F is reduced by the operation of the ABS unit 58F, so that the brake lever 20F is operated even after the front wheels 14 return to the normal state. If so, the front wheel 14 may be likely to lock again. Based on this point, the bicycle device 56 reduces the hydraulic pressure applied to the caliper 28F, so that the control device 60 performs steps S16 to S18 after the front wheels 14 have returned to the normal state. . For this reason, even if the wheel is about to lock again, the ABS unit 58F is activated again, and the user is unlikely to lose balance.

(Second Embodiment)
The bicycle device 56 of the second embodiment is different from the bicycle device 56 of the first embodiment in the points described below, and has substantially the same configuration as the bicycle device 56 of the first embodiment in other points. Prepare. In the description of the bicycle device 56 of the second embodiment, the same reference numerals are given to the components common to the bicycle device 56 of the first embodiment, and a part or all of the description of the configuration is omitted.

  FIG. 5 shows an electrical or mechanical connection relationship of the bicycle 10 (see FIG. 1). The broken line in FIG. 5 indicates the electrical connection relationship of the bicycle 10. Also, the solid line in FIG. 5 indicates the mechanical connection relationship of the bicycle 10.

  The bicycle device 56 includes an ABS unit that is driven by the assist motor 36 and controls braking force applied to the wheels from the calipers 28F and 28R. The ABS unit includes a first ABS unit 58F that controls the braking force applied to the front wheels 14 (see FIG. 1), and a second ABS unit 58R that controls the braking force applied to the rear wheels 16 (see FIG. 1). . Each ABS unit 58 </ b> F, 58 </ b> R is accommodated in the internal space of the housing 38. The control device 60 controls the assist motor 36, the first ABS unit 58F, and the second ABS unit 58R. Since the first ABS unit 58F has substantially the same configuration as the ABS unit 58F of the first embodiment, a part or all of the description thereof is omitted.

  The second ABS unit 58R includes a pump 62 that is common to the first ABS unit 58F, and a reservoir 64R that stores hydraulic oil. The pump 62 is a common component in the ABS units 58F and 58R, and has a role of applying hydraulic pressure to the calipers 28F and 28R. A pump 62 may be provided for each of the ABS units 58F and 58R.

  The second ABS unit 58R further includes a first valve 68R and a second valve 70R that adjust the hydraulic pressure applied to the caliper 28R. The first valve 68R has substantially the same configuration as the first valve 68F in the first ABS unit 58F, and is arranged in a pipe line connecting the brake lever 20R and the caliper 28R. The second valve 70R has substantially the same configuration as the second valve 70F in the first ABS unit 58F, and is disposed in a pipe line connecting the caliper 28R and the reservoir 64R.

  When the hydraulic pressure applied to the caliper 28R is large, the caliper 28R is brought closer to the disk rotor 26R (see FIG. 1). In this case, the caliper 28R sandwiches the disc rotor 26R via the brake pad, and the rotation of the rear wheel 16 is braked. On the other hand, when the hydraulic pressure applied to the caliper 28R is small, the caliper 28R moves away from the disk rotor 26R. For this reason, the rotation of the rear wheel 16 is not braked.

  The hydraulic oil supplied from the pump 62 flows through the first pipe line 72F, the second pipe line 74F, and the third pipe line 76F in the first ABS unit 58F, and at the same time, the second ABS unit 58R. Flow in the first pipe line 72R, the second pipe line 74R, and the third pipe line 76R. The first pipe line 72R, the second pipe line 74R, and the third pipe line 76R are pipe lines branched into three, respectively.

  Each end of the first pipe line 72R is connected to the brake lever 20R, the pump 62, and the first valve 68R. The first pipe line 72R is connected to the pump 62 by being connected to a portion of the first pipe line 72F between the pump 62 and the first check valve 78F. Each end of the second pipe line 74R is connected to the caliper 28R, the first valve 68R, and the second valve 70R. Each end of the third conduit 76R is connected to the pump 62, the reservoir 64R, and the second valve 70R. The third conduit 76R is connected to the pump 62 by being connected to a portion of the third conduit 76F between the pump 62 and the second check valve 80F.

  The second ABS unit 58R further includes a first check valve 78R arranged in the first pipe line 72R and a second check valve 80R arranged in the third pipe line 76R. The first check valve 78R has substantially the same configuration as the first check valve 78F in the first ABS unit 58F. The second check valve 80R has substantially the same configuration as the second check valve 80F in the first ABS unit 58F.

  The bicycle 10 further includes a first detection device 82R that detects an operation state of the brake lever 20R. The first detection device 82R has substantially the same configuration as the first detection device 82F. The first detection device 82R is electrically connected to the control device 60.

  The operation unit 86 is configured to switch between an ABS operation mode for switching the ABS units 58F and 58R to an operable state and an ABS non-operation mode for switching the ABS units 58F and 58R to a non-operating state (not shown). Abbreviation).

  The control device 60 controls the output and rotation direction of the assist motor 36 based on the detection results of the first detection devices 82F and 82R and the second detection devices 84F and 84R. Based on the detection results of the first detection devices 82F and 82R and the second detection devices 84F and 84R, the control device 60 opens and closes the first valve 68F and the second valve 70F in the first ABS unit 58F. In addition, the open / close states of the first valve 68R and the second valve 70R in the second ABS unit 58R are individually switched. The control related to switching of the open / closed states of the valves 68R and 70R in the second ABS unit 58R is substantially the same as the control related to switching of the open / closed states of the valves 68F and 70F in the first ABS unit 58F.

The control device 60 starts the processing shown in FIGS. 3 and 4 when the operation unit 86 is set to the ABS operation mode.
In step S1, step S10, and step S16, the control device 60 determines whether or not the brake levers 20F and 20R are operated based on the first detection devices 82F and 82R. When at least one of the brake levers 20F and 20R is operated, it is determined that the brake levers 20F and 20R are operated.

  In step S6, the control device 60 executes at least one of the first valve 68F and the second valve 70F in the first ABS unit 58F and the first valve 68R and the second valve 70R in the second ABS unit 58R. One open / close state is switched from the first pattern to the second pattern.

  For example, the control device 60 activates the ABS units 58F and 58R corresponding to the wheel in which the change in the rotational speed of the predetermined value or more is detected in step S4. That is, when it is determined in step S4 that the change in rotational speed of the rear wheel 16 is greater than or equal to a predetermined value, the control device 60 determines in step S6 the first valve 68R and the second valve unit 58R in the second ABS unit 58R. The open / close state of the second valve 70R is switched from the first pattern to the second pattern.

  For example, when it is detected in step S4 that the difference between the rotational speed of the front wheel 14 and the rotational speed of the rear wheel 16 is equal to or greater than a predetermined speed, the control device 60 corresponds to the wheel having the lower rotational speed. The ABS units 58F and 58R are operated. That is, when it is determined in step S4 that the rotational speed of the rear wheel 16 is lower than the rotational speed of the front wheel 14 by a predetermined speed or more, the control device 60 determines in step S6 the first valve 68R and the second valve unit 68R in the second ABS unit 58R. The open / close state of the second valve 70R is switched from the first pattern to the second pattern. Note that step S14 is the same as step S6.

The operation of the bicycle device 56 will be described with reference to FIGS. 1 and 5.
When the user operates the brake levers 20F and 20R when the vehicle speed is equal to or higher than the predetermined speed, at least one of the front wheel 14 and the rear wheel 16 depends on the road surface or the strength with which the user holds the brake levers 20F and 20R. May lock. At this time, the assist motor 36 and the ABS units 58F and 58R are controlled by the control device 60, and the braking force applied to the wheels of the bicycle 10 is controlled.

  For this reason, even if at least one of the front wheels 14 and the rear wheels 16 is likely to be locked in accordance with the operation of the brake levers 20F and 20R, the ABS units 58F and 58R are driven by the control device 60, and the wheels are brought into a normal state. Return. For this reason, it becomes difficult for the user to lose balance during traveling.

According to the bicycle device 56 of the second embodiment, in addition to the effects (1) to (5) obtained by the first embodiment, the following effects are further obtained.
(6) The bicycle device 56 includes a first ABS unit 58F that controls the braking force applied to the front wheels 14, and a second ABS unit 58R that controls the braking force applied to the rear wheels 16. For this reason, even if one or both of the front wheels 14 and the rear wheels 16 are likely to be locked in accordance with the operation of the brake levers 20F and 20R, the ABS units 58F and 58R are actuated to operate the front wheels 14 and the rear wheels. 16 returns to the normal state. For this reason, compared with a configuration including only one of the first ABS unit 58F and the second ABS unit 58R, the user is less likely to lose balance during traveling.

(Modification)
The description regarding each said embodiment is an illustration of the form which the apparatus for bicycles according to this invention can take, and it does not intend restrict | limiting the form. The bicycle apparatus according to the present invention may take a form in which, for example, a modification of the embodiment shown below and at least two modifications not contradicting each other are combined. In the following modified examples, the same reference numerals as those in the embodiment are given to portions common to the embodiment, and the description thereof is omitted.

  -The control apparatus 60 of a modification performs simultaneously the process of step S6, and the process of step S7 in ABS operation control. In the ABS operation control, the control device 60 of another modified example executes the process of step S7 before the process of step S6.

  -According to the control device 60 of the modified example, in the ABS operation control, the processes in steps S16 to S18 are omitted from the processes shown in FIGS.

  -According to the control device 60 of the modification, the process of step S19 is omitted from the processes shown in FIGS. 3 and 4 in the ABS operation control. According to this modification, it is preferable to use the assist motor 36 having high performance capable of driving the pump 62 so as to increase the amount of hydraulic pressure in a short time.

  According to the control device 60 of the modified example, the rotational speed of the front wheel 14 and the speed of the rear wheel 16 are determined from the predetermined state determined in the processing of step S4, step S13, and step S18 shown in FIGS. A state where the difference from the rotational speed is equal to or higher than the predetermined speed is omitted.

  The modified first detection devices 82F and 82R are hydraulic sensors that detect the hydraulic pressures of the first pipe lines 72F and 72R instead of the angle sensors. The hydraulic pressure sensor is realized by, for example, a pressure sensor provided on the inner walls of the first pipelines 72F and 72R.

  The operation device of the modified example includes a grip in which the rotation of the wheel is braked by rotating the handle 18 around the axis of the handle 18 instead of the brake levers 20F and 20R. According to this modification, the braking force applied to the wheel is adjusted according to the rotation amount of the grip. The operating device of another modified example includes a button attached to the handle 18 instead of the brake levers 20F and 20R. According to this another modification, the braking force applied to the wheel is adjusted according to the amount of pressing the button.

  The modified braking devices 22F and 22R are, for example, rim brakes or cantilever brakes instead of the disc brakes.

  -The bicycle apparatus 56 of the modification of 1st Embodiment is provided with the ABS unit 58R which controls the braking force given to the rear wheel 16 instead of the ABS unit 58F. The ABS unit 58R has substantially the same configuration as the second ABS unit 58R of the second embodiment.

  According to the bicycle apparatus 56 of the modification of the first embodiment, the ABS unit 58F is attached to the outside of the housing 38. As shown in FIG. 6, the bicycle device 56 further includes a case 88 attached to the outside of the housing 38, for example. According to this modification, the ABS unit 58 </ b> F is accommodated in the internal space of the case 88. In the second embodiment, the same modification is established. According to the bicycle apparatus 56 of the modification of the second embodiment, for example, at least one of the first ABS unit 58F and the second ABS unit 58R is accommodated in the internal space of the case 88.

  The bicycle device 56 according to the modified example of the first embodiment houses the pump 62 of the ABS unit 58F in the internal space of the housing 38, and arranges other elements of the ABS unit 58F outside the housing 38. According to this modification, the other elements of the ABS unit 58F are accommodated in the internal space of the case attached to the outside of the housing 38, for example. In the second embodiment, the same modification is established.

  According to the bicycle apparatus 56 of the modification, the control of the ABS units 58F and 58R by the control apparatus 60 depends on the operation of the assist selection switch. For example, when the assist-on mode is selected, the operation mode is always switched to the ABS operation mode.

  -According to the bicycle 10 of the modified example, the ABS operation changeover switch is omitted from the operation unit 86. According to this modification, for example, when the assist-on mode is selected by the assist selection switch, the ABS operation mode is switched. On the other hand, when the assist-off mode is selected by the assist selection switch, the mode is switched to the ABS non-operation mode.

DESCRIPTION OF SYMBOLS 10 ... Bicycle, 14 ... Front wheel, 16 ... Rear wheel, 20F, 20R ... Brake lever (operating device), 22F, 22R ... Brake device, 34 ... Crankshaft, 36 ... Assist motor, 38 ... Housing, 56 ... Bicycle device 58F, 58R ... ABS unit, 60 ... control device, 62 ... pump, 66 ... one-way clutch, 82F, 82R ... first detection device, 84F, 84R ... second detection device.

  An object of the present invention is to provide a bicycle device for suitably braking a bicycle.

  The bicycle apparatus according to the first aspect of the present disclosure includes an ABS unit that controls a braking force applied to a bicycle wheel, an ABS operation mode in which the ABS unit is operable, and a state in which the ABS unit is not activated. And an ABS operation changeover switch for switching between the ABS non-operation modes.
  The bicycle apparatus according to the second aspect according to the first aspect of the present disclosure further includes a control device that controls the ABS unit.
  In the bicycle apparatus according to the third aspect according to the second aspect of the present disclosure, the control device is configured so that when the ABS operation changeover switch is switched to the ABS operation mode, a braking force is applied to the bicycle wheel. Control the unit.
  In the bicycle device according to the fourth aspect according to the third aspect of the present disclosure, the control device is turned on when the ABS operation changeover switch is switched to the ABS operation mode, and the ABS operation changeover switch is not activated by the ABS. Turns off when switching to mode.
  In the bicycle apparatus according to the fifth aspect according to any one of the second to fourth aspects of the present disclosure, an assist selection for selecting an operation mode of the assist motor of the bicycle between an assist-on mode and an assist-off mode. An operation unit including a switch is further provided.
  In the bicycle device according to the sixth aspect according to the fifth aspect of the present disclosure, the control of the ABS unit by the control device is an operation of the assist selection switch for selectively supplying and cutting off power to the assist motor of the bicycle. Does not depend on.
  In the bicycle device according to the seventh aspect according to the fifth or sixth aspect of the present disclosure, the control of the ABS unit by the control device is executed by the ABS operation changeover switch that switches the ABS unit to the ABS operation mode. In this respect, the control of the ABS unit by the control device does not depend on the operation of the assist selection switch.
  In the bicycle apparatus according to the eighth aspect according to the fifth aspect of the present disclosure, the control of the ABS unit by the control device is an operation of the assist selection switch for selectively supplying and shutting off power to the bicycle assist motor. Depends on.
  In the bicycle device according to the ninth aspect of the fifth or eighth aspect of the present disclosure, the operation mode of the ABS unit is always switched to the ABS operation mode when the assist-on mode is selected.
  The bicycle apparatus according to the tenth aspect according to any one of the second to ninth aspects of the present disclosure, further comprising the bicycle assist motor that drives the ABS unit, wherein the bicycle assist motor is controlled by the control device. Be controlled.
  In the bicycle apparatus according to the eleventh aspect according to the tenth aspect of the present disclosure, the assist motor of the bicycle adds an assist force to a human driving force input from a crankshaft of the bicycle.
  In the bicycle apparatus according to the twelfth aspect according to the tenth or eleventh aspect of the present disclosure, the control device controls the assist motor and the ABS unit of the bicycle based on a rotational speed of at least one of the bicycle wheels. .
  In the bicycle apparatus according to the thirteenth aspect according to any one of the tenth to twelfth aspects of the present disclosure, the control device drives the bicycle assist motor to increase the hydraulic pressure, and the brake lever is operated. If it is determined that there is not, the rotation of the assist motor of the bicycle for increasing the hydraulic pressure is stopped.
  In the bicycle apparatus according to the fourteenth aspect according to the thirteenth aspect of the present disclosure, the control device is configured to increase the hydraulic pressure when determining that the rotational speed of at least one of the bicycle wheels is less than a predetermined speed. The bicycle assist motor stops rotating.
  In the bicycle apparatus according to the fifteenth aspect according to any one of the tenth to fourteenth aspects of the present disclosure, the ABS unit further includes a pump that applies hydraulic pressure to the bicycle braking device, and the pump includes the bicycle It is driven by an assist motor.
  In the bicycle apparatus according to the sixteenth aspect according to the fifteenth aspect of the present disclosure, the control device increases the hydraulic pressure applied to the bicycle braking device after the hydraulic pressure applied to the bicycle braking device is reduced. Control the pump.
  The bicycle apparatus according to the seventeenth aspect according to any one of the second to sixteenth aspects of the present disclosure further includes a first detection device that detects an operation state of the brake lever of the bicycle, wherein the first detection device includes: A detection result is output to the control device.
  In the bicycle device according to the eighteenth aspect according to the seventeenth aspect of the present disclosure, the control device reduces the output of the assist motor of the bicycle when determining that the brake lever of the bicycle is operated.

  A bicycle apparatus according to the first aspect of the present disclosure includes an ABS unit that is driven by an assist motor that adds an assist force to a human-powered drive force that is input from a bicycle crankshaft and that controls a braking force applied to the bicycle wheel. The ABS unit includes a pump that applies hydraulic pressure to a braking device that applies braking force to the wheels, and the pump is driven by the assist motor.
  The bicycle apparatus according to the 2A side according to the 1A side of the present disclosure further includes the assist motor.
  In the bicycle apparatus according to the 3A side according to the 1A or 2A side of the present disclosure, an assist force is added to the human driving force by rotating the assist motor in a first direction, and the assist motor is The pump is driven by rotating in a second direction opposite to the direction of.
  In the bicycle apparatus according to the 4A side according to the 3A side of the present disclosure, when the assist motor rotates in the first direction, no driving force is transmitted from the assist motor to the pump, and the assist motor And a one-way clutch that transmits a driving force from the assist motor to the pump when rotated in the direction of 2.
  The bicycle apparatus according to the fifth A side according to any one of the first to fourth A side surfaces of the present disclosure further includes a control device that controls the assist motor and the ABS unit.
  In the bicycle device according to the 6A side according to the 5A side of the present disclosure, the control device detects a first detection device that detects an operation state of the operation device connected to the braking device, and detects a rotation state of the wheel. The assist motor and the ABS unit are controlled based on the detection result of the first detection device and the detection result of the second detection device.
  In the bicycle apparatus according to the seventh A side according to the sixth A side of the present disclosure, an assist force is added to the human power driving force by rotating the assist motor in a first direction, and the assist motor is moved in the first direction. When the pump is driven by rotating in the opposite second direction, and the control device rotates the assist motor in the first direction, the assist device is operated when the operation device is operated. The output of the motor in the first direction is reduced.
  In the bicycle apparatus according to the 8A side according to the 6A or 7A side of the present disclosure, the control device is a hydraulic pressure applied to the braking device based on a rotation state of the wheel when the operation device is operated. Is reduced by the ABS unit, and the assist motor is rotated in the second direction.
  In the bicycle device according to the 9A side according to the 8A side of the present disclosure, when the control device rotates the assist motor in the second direction, the operation device is not operated. The rotation of the assist motor in the second direction is stopped.
  In the bicycle apparatus according to the 10A side according to the 8A or 9A side of the present disclosure, when the control device rotates the assist motor in the second direction, the rotation speed of the wheels is less than a predetermined speed. In this state, rotation of the assist motor in the second direction is stopped.
  In the bicycle apparatus according to the 11A side according to any one of the 8A to 10A sides of the present disclosure, the control device increases the hydraulic pressure by the pump after the hydraulic pressure applied to the braking device is reduced. .
  The bicycle apparatus according to the twelfth side according to any one of the first to eleventh side aspects of the present disclosure further includes a housing in which the assist motor and the ABS unit are provided.
  In the bicycle apparatus according to the thirteenth aspect according to the twelfth aspect of the present disclosure, the pump of the ABS unit is provided in an internal space of the housing.
  In the bicycle device according to the 14A side according to any one of the 1A to 13A sides of the present disclosure, the wheel includes a front wheel and a rear wheel, and the ABS unit controls a braking force applied to the front wheel. 1 ABS unit and a second ABS unit for controlling the braking force applied to the rear wheel.

According to the bicycle device of the present disclosure, the bicycle can be suitably braked.

Claims (14)

An ABS unit that is driven by an assist motor that adds an assist force to a manpower driving force input from a bicycle crankshaft and that controls a braking force applied to the bicycle wheel;
The ABS unit includes a pump that applies hydraulic pressure to a braking device that applies a braking force to the wheels,
The bicycle device is driven by the assist motor. The bicycle apparatus according to claim 1, further comprising the assist motor. When the assist motor rotates in the first direction, an assist force is added to the human power driving force, and when the assist motor rotates in the second direction opposite to the first direction, the pump is driven. The bicycle apparatus according to claim 1 or 2. When the assist motor rotates in the first direction, no driving force is transmitted from the assist motor to the pump, and when the assist motor rotates in the second direction, the assist motor drives the pump. The bicycle apparatus according to claim 3, further comprising a one-way clutch that transmits force. The bicycle apparatus according to claim 1, further comprising a control device that controls the assist motor and the ABS unit. The control device is connected to a first detection device that detects an operation state of an operation device connected to the braking device, and a second detection device that detects a rotation state of the wheel,
The bicycle apparatus according to claim 5, wherein the assist motor and the ABS unit are controlled based on a detection result of the first detection device and a detection result of the second detection device. The control device reduces the output of the assist motor in the first direction when the operation device is operated while rotating the assist motor in the first direction. The bicycle device according to claim 6, which is cited automatically or indirectly. The control device reduces the hydraulic pressure applied to the braking device by the ABS unit based on the rotation state of the wheel when the operation device is operated, and moves the assist motor in the second direction. The bicycle device according to claim 6 or 7, wherein the bicycle device is rotated. The control device stops rotation of the assist motor in the second direction when the operation device is not operated when the assist motor is rotated in the second direction. Item 9. The bicycle device according to Item 8. The control device stops the rotation of the assist motor in the second direction when the rotation speed of the wheel is less than a predetermined speed while rotating the assist motor in the second direction. The bicycle apparatus according to claim 8 or 9. The bicycle apparatus according to any one of claims 8 to 10, wherein the control device increases the hydraulic pressure by the pump after the hydraulic pressure applied to the braking device is reduced. The bicycle apparatus according to any one of claims 1 to 11, further comprising a housing in which the assist motor and the ABS unit are provided. The bicycle apparatus according to claim 12, wherein the pump of the ABS unit is provided in an internal space of the housing. The wheel includes a front wheel and a rear wheel,
The ABS unit includes a first ABS unit that controls braking force applied to the front wheels, and a second ABS unit that controls braking force applied to the rear wheels. The bicycle device as described.