JP5873000B2 - Electric assist bicycle - Google Patents

Description

  The present invention relates to a battery-assisted bicycle that uses an electric motor to generate an auxiliary driving force corresponding to an input torque generated by a pedaling force applied to a pedal, and drives a wheel auxiliary by the auxiliary driving force.

  2. Description of the Related Art An electrically assisted bicycle is known that includes a human-powered drive system that supplies a pedal force applied to a pedal to a wheel and an auxiliary drive force drive system that supplies an auxiliary drive force from an electric motor to the wheel according to the pedal force applied to the pedal ing. In the battery-assisted bicycle, the type that transmits the pedaling force applied to the pedal to the rear wheel and the auxiliary driving force by the motor to the front wheel, and the pedaling force applied to the pedal and the auxiliary driving force by the motor are both used. There is a type that transmits to the rear wheel.

  In particular, in the case of driving the front wheels with an electric motor, the load on the front wheels is small in situations such as starting uphill, and therefore slip (idling) tends to occur on the front wheels. In addition, if the front wheel slips in a situation where the steering wheel is turned, the vehicle body may slip and fall over. On the other hand, when the rear wheels are driven by an electric motor, both the driving force by the stepping force and the auxiliary driving force by the motor are transmitted to the rear wheels, so that the rear wheels are driven with a relatively large torque. Therefore, when traveling on a wet road surface, a frozen road surface, or the like, slip easily occurs on the rear wheels. As described above, in the battery-assisted bicycle, wheel slipping is more likely to occur compared to a motorcycle due to specific circumstances such as a light vehicle body, thin tires, and a front wheel drive type.

  As a technique related to wheel slip countermeasures in a battery-assisted bicycle, Patent Document 1 detects a rotational difference between a front wheel driven by an electric motor and a rear wheel driven by a pedaling force, and the front wheel rotates faster than a rear wheel. If it is determined that the front wheel is slipping and slipping of the front wheel is detected, the energization of the electric motor is stopped, or the energization is limited to reduce the rotational torque of the front wheel, or the rotation speed of the motor It is described to control.

  On the other hand, in Patent Document 2, the rear wheel vehicle speed is obtained from the pedal force detection value input from the pedal force sensor, the front wheel vehicle speed is obtained from the motor voltage, current, etc., and when the front wheel vehicle speed is higher than the rear wheel vehicle speed, It is described that it is determined that a slip has occurred. Further, as another method of slip detection, it is described that it is determined that a slip has occurred when the rate of increase of the front wheel vehicle speed obtained from the rotational speed of the electric motor is equal to or greater than a predetermined value. Further, in Patent Document 2, when it is determined that slip has occurred, the assist ratio in the assist force drive system is decreased, the decreased assist ratio is maintained for a predetermined time, and then gradually increased to the original. It is described that the auxiliary ratio is restored.

JP 2004-142634 A Japanese Patent No. 4365113

  As described in Patent Document 2 above, even if the auxiliary ratio is gradually decreased after the slip ratio is reduced, the slip ratio is likely to be generated even after the recovery of the assist ratio even in the case of rain. Since this continues, slip recurrence cannot be prevented. Thus, in the conventional battery-assisted bicycle, there is still room for improvement in the output control of the electric motor after the slip detection.

  The present invention has been made in view of the above-described points, and an object thereof is to provide a battery-assisted bicycle that can prevent the recurrence of a slip when a slip of a wheel driven by an electric motor is detected. .

The battery-assisted bicycle according to the first aspect of the present invention includes an auxiliary drive system that generates an auxiliary drive force according to an input torque generated by a pedaling force applied to a pedal by an electric motor, and drives a wheel by the auxiliary drive force; A slip occurrence detecting means for detecting the occurrence of wheel slip, and a ratio of the magnitude of the auxiliary driving force to the magnitude of the input torque due to the pedal force when the slip of the wheel is detected by the slip occurrence detecting means. The output of the electric motor is controlled so that a certain assist ratio is smaller than the magnitude before the detection of the wheel slip, and the electric motor is controlled so that the assist ratio becomes smaller than the magnitude before the detection of the wheel slip. reed when depression number of said pedal from controlling the output reaches a predetermined number, as the release condition is satisfied Comprising a control means preparative ratio controls the output of the electric motor such that the magnitude of the previous detection of the slip of the wheels, the.

  The control means controls the output of the electric motor so that the assist ratio is smaller than the magnitude before detection of the wheel slip, and the assist ratio is detected before the detection of the wheel slip when a predetermined period has elapsed. You may control the output of the said electric motor so that it may become the magnitude | size.

  The battery-assisted bicycle according to the second aspect of the present invention includes an auxiliary drive system that generates an auxiliary drive force according to an input torque generated by a pedaling force applied to a pedal by an electric motor, and drives a wheel by the auxiliary drive force; A slip occurrence detecting means for detecting the occurrence of wheel slip, and a ratio of the magnitude of the auxiliary driving force to the magnitude of the input torque due to the pedal force when the slip of the wheel is detected by the slip occurrence detecting means. The output of the electric motor is controlled so that a certain assist ratio is smaller than the magnitude before the detection of the wheel slip, and the electric motor is controlled so that the assist ratio becomes smaller than the magnitude before the detection of the wheel slip. Canceled when the slip occurrence detecting means does not detect the wheel slip for a predetermined period after controlling the output. Assist ratio as matter is satisfied and a control means for controlling the output of the electric motor such that the magnitude of the previous detection of the slip of the wheel.

  The battery-assisted bicycle according to a third aspect of the present invention includes an auxiliary drive system that generates an auxiliary drive force according to an input torque generated by a pedaling force applied to a pedal by an electric motor, and drives a wheel by the auxiliary drive force; Slip occurrence detection means for detecting the occurrence of wheel slip, determination means for determining the magnitude of slip generated in the wheel, and input by the tread force when the slip of the wheel is detected by the slip occurrence detection means The assist ratio, which is the ratio of the magnitude of the auxiliary driving force to the magnitude of the torque, is smaller than the magnitude before the detection of the slip of the wheel, and the magnitude of the slip determined by the judging means is larger. The output of the electric motor is reduced so that the assist ratio from when the slip is detected until the predetermined release condition is satisfied is reduced. Gyoshi, and a control means for the assist ratio to control the output of the electric motor such that the magnitude of the previous detection of the slip of the wheels when said predetermined cancellation condition is satisfied.
  The battery-assisted bicycle according to the first or second aspect of the present invention may further include determination means for determining the scale of slip generated in the wheel. In this case, the control means is determined by the determination means. The larger the scale of the slip, the smaller the assist ratio from the detection of the wheel slip until the release condition is satisfied. In the battery-assisted bicycle according to the first to third aspects of the present invention, the control unit may change the release condition according to the size of the slip determined by the determination unit.

  According to the battery-assisted bicycle according to the present invention, it is possible to prevent the slip from recurring after detecting the slip of the wheel driven by the electric motor.

1 is a side view showing a configuration of a battery-assisted bicycle according to an embodiment of the present invention. It is a block diagram which shows the structure of the motor control system which concerns on embodiment of this invention. FIGS. 3A to 3C are diagrams showing time transitions of the input torque detection signal, the motor output command value, the motor torque detection signal, and the rotation speed detection signal according to the embodiment of the present invention, respectively. . FIG. 4A is a diagram showing a time transition of the motor torque detection signal at the start of the battery-assisted bicycle according to the embodiment of the present invention. FIG. 4B is a diagram showing a time transition of the rotation speed detection signal when the battery-assisted bicycle according to the embodiment of the present invention starts. Fig.5 (a) is a figure which shows the time transition of the motor torque detection signal at the time of driving | running | working of the battery-assisted bicycle which concerns on embodiment of this invention. FIG.5 (b) is a figure which shows the time transition of the rotation speed detection signal at the time of driving | running | working of the battery-assisted bicycle which concerns on embodiment of this invention. It is a flowchart which shows the flow of a process in the slip detection process program which concerns on embodiment of this invention. FIG. 7A and FIG. 7B are diagrams showing a time transition of the assist ratio in the electric motor when the slip elimination process according to the embodiment of the present invention is executed. It is a flowchart which shows the flow of a process in the slip cancellation processing program which concerns on embodiment of this invention. It is the figure which showed the time transition of the motor torque detection signal and the rotation speed detection signal when the slip of the front wheel which concerns on embodiment of this invention is eliminated. FIG. 10A is a diagram showing a time transition of the assist ratio during the motor output recovery process according to the embodiment of the present invention. FIG.10 (b) is the figure which showed the time transition of the torque upper limit value in the electric motor during the motor output recovery process which concerns on embodiment of this invention. It is a flowchart which shows the flow of a process in the traveling control program which concerns on embodiment of this invention. It is a flowchart which shows the flow of a process in the slip detection process program which concerns on other embodiment of this invention. FIG. 13A and FIG. 13B are diagrams showing the time transition of the assist ratio during the slip elimination process according to another embodiment of the present invention. It is a flowchart which shows the flow of the process in the slip cancellation processing program which concerns on other embodiment of this invention. It is the figure which showed the time transition of the motor torque detection signal in the slip cancellation process which concerns on embodiment of this invention. FIG. 16A is a diagram showing a time transition of the assist ratio during the output recovery process according to another embodiment of the present invention. FIG. 16B is a diagram showing a time transition of the torque upper limit value of the electric motor during the output recovery process according to another embodiment of the present invention. It is a flowchart which shows the flow of a process in the assist mode switching process program which concerns on embodiment of this invention. It is a figure which shows the waveform of the input torque signal output from the input torque detection part which concerns on embodiment of this invention. It is a flowchart which shows the flow of a process in the assist mode switching process program which concerns on other embodiment of this invention.

Embodiments of the present invention will be described below with reference to the drawings. In the drawings, the same or equivalent components and parts are denoted by the same reference numerals. Further, in the following description, the case where the present invention is applied to a type of battery-assisted bicycle that drives the rear wheels with the pedaling force applied to the pedal by the driver and drives the front wheels with the auxiliary driving force by the electric motor is illustrated. .
[First embodiment]
The battery-assisted bicycle 1 has a frame including a front fork 11, a head pipe 12, a down tube 13, a seat tube 14, a seat stay 15, and a chain stay 16. The front wheel 21 is rotatably attached to the front fork 11, and the rear wheel 22 is rotatably attached to the intersection of the seat stay 15 and the chain stay 16.

  A handle stem 23 is rotatably inserted into the head pipe 12, and a handle 24 is attached to the upper end of the handle stem 23. On the other hand, a seat post 25 is fitted to the seat tube 14, and a saddle 26 is attached to the upper end of the seat post 24.

  The pedal 27 is connected to a sprocket (not shown) via a crank 28. The sprocket rotates when the driver applies pedaling force to the pedal 27, and the driving force is transmitted to the rear wheel 22 via the chain 29 as the sprocket rotates.

  The electric motor 30 is mounted on the axle of the front wheel 21 and generates a driving force that rotates the front wheel 21. The rotation of the electric motor 30 is decelerated by a reduction mechanism (not shown) and transmitted to the front wheels 21. The electric motor 30 can be composed of, for example, a brushless DC motor.

  Electric power for driving the electric motor 30 is supplied from a battery 31 detachably provided along the seat tube 14. The battery 31 is composed of, for example, a lithium ion secondary battery, and can be repeatedly used by charging.

  FIG. 2 is a block diagram showing a configuration of a motor control system for performing output control of the electric motor 30 in the battery-assisted bicycle 1.

  The power supply circuit 41 is configured to include, for example, a chopper step-down DC-DC converter, steps down a DC voltage output from the battery 31, and supplies this to the MCU 50 as a drive voltage of an MCU (Micro Controller Unit) 50. .

  The input torque detector 42 detects a pedaling force (torque) when the driver steps on the pedal, and supplies an input torque detection signal indicating the magnitude of the detected input torque to the MCU. For example, the input torque detector 42 is provided with an elastic body such as a spring that is displaced according to the input torque between the crankshaft of the crank 28 and a sprocket (not shown), and is elastic at the rotating portion according to the input torque. It includes a known torque sensor that converts the amount of body displacement into the amount of displacement at the fixed part using a cam or planetary gear, etc., and converts this amount of displacement into an electrical signal using a potentiometer or the like. Also good. Further, the input torque detection unit 42 may include a known non-contact type torque sensor including a magnetostrictive material having a magnetostrictive effect and a detection coil.

  The operation / display unit 43 includes an operation input unit including a power switch that switches activation and deactivation of the entire control system illustrated in FIG. 2, an assist mode switching switch that switches the magnitude of the auxiliary driving force by the electric motor, and a traveling speed. And a display unit for displaying the remaining battery level and the like. An operation input to the operation unit is provided to the MCU 50 via a signal wiring (not shown). The display unit performs various displays based on information shared from the MCU 50. The operation / display unit 43 is attached to, for example, the handle 24 so that the driver can easily operate and view the operation / display surface.

  The motor drive circuit 44 extracts drive power for driving the electric motor 30 from the battery 31 based on the control signal supplied from the MCU 50 and supplies the drive power to the electric motor 30. The motor drive circuit 44 may drive the electric motor 30 by, for example, a PWM (pulse width modulation) method. The electric motor 30 generates an auxiliary driving force corresponding to the driving power supplied from the motor driving circuit 44 and rotationally drives the front wheels 21.

  The motor torque detector 45 detects the torque of the electric motor 30 and supplies a motor torque detection signal indicating the magnitude of the detected torque to the MCU 50. Here, the torque generated by the electric motor 30 is proportional to the current supplied to the electric motor 30. Therefore, the motor torque detector 45 may detect the torque of the electric motor 30 based on the current supplied to the electric motor 30.

  The motor rotation speed detection unit 46 detects the rotation speed of the electric motor 30 and supplies a rotation speed detection signal indicating the detected rotation speed to the MCU 50. For example, when the electric motor 30 is configured by a brushless DC motor, a magnetic sensor such as a Hall element is provided along with the electric motor 30 in order to detect the rotational position of the magnet rotor. In the present embodiment, the motor rotation speed detection unit 46 includes a magnetic sensor provided along with the electric motor 30 and detects the rotation speed of the electric motor 30 based on an output signal of the magnetic sensor. . The motor rotation speed detection unit 46 may be configured to include a known rotation detector (encoder) that reads light from a light source such as a light emitting diode with a light receiving element through a position detection pattern on a slit disk. .

  The MCU 50 is an LSI (Large Scale Integration) in which a computer system including a CPU, a memory, an input / output circuit, a timer circuit, and the like is integrated on a single semiconductor chip. The MCU 50 derives an assist ratio suitable for the driving situation by calculation based on various signals supplied from the input torque detector 42, the motor torque detector 45, and the motor rotation speed detector 46. For example, when the rotational speed of the electric motor 30 is low and the torque of the electric motor 30 is large, it is presumed that the state is immediately after starting or a state where the vehicle is traveling uphill. Supplies a motor output command value to the motor drive circuit 44 to generate a larger auxiliary drive force.

  Further, the MCU 50 detects slip in the front wheels 21 driven by the electric motor 30 based on the motor torque detection signal supplied from the motor torque detection unit 45 and the rotation speed detection signal supplied from the motor rotation number detection unit 46. Execute slip detection processing. The slip detection process in the MCU 50 will be described later.

  Further, when the front wheel 21 slips, the MCU 50 cancels the ratio of the auxiliary driving force by the electric motor 30 to the input torque due to the pedaling force (hereinafter referred to as the assist ratio) until the slip at the front wheel 21 is eliminated. The slip elimination process is executed to gradually lower the speed until The slip elimination process in the MCU 50 will be described later.

  Further, the MCU 50 executes a motor output recovery process for recovering the output of the electric motor 30 by gradually increasing the assist ratio in the electric motor 30 after the slip of the front wheel 21 is eliminated by the above-described slip cancellation process. The motor output recovery process in the MCU 50 will be described later.

<Slip detection processing>
Below, the slip detection process performed in MCU50 is demonstrated. Here, FIGS. 3A to 3C are respectively an input torque detection signal indicating an input torque generated in the crankshaft by a pedaling force applied to the pedal 27 by the driver, and motor driving from the MCU 50 according to the input torque. The time transition of the motor output command value supplied to the circuit 44, the motor torque detection signal indicating the torque of the electric motor 30 driven in accordance with the motor output command value, and the rotation speed detection signal indicating the rotation speed of the electric motor 30 FIG. FIG. 3A shows a case where no slip occurs on the front wheel 21 at the start, FIG. 3B shows a case where slip occurs on the front wheel 21 at the start, and FIG. The case where a slip occurs in the front wheel 21 during traveling is shown.

  As shown in FIG. 3A, when the motor output command is issued from the MCU 50 when the battery-assisted bicycle 1 is started, the electric motor 30 starts to rotate. When the front wheel 21 is not slipped, the rotational speed of the electric motor 30 rises relatively slowly, so that the rotational speed detection signal rises with a relatively gentle slope. On the other hand, since the torque of the electric motor 30 suddenly increases from the start of rotation, the motor torque detection signal rises sharply.

  As shown in FIG. 3B, when the front wheel 21 slips from the start of the start of the battery-assisted bicycle 1, the load on the electric motor 30 is smaller than when no slip occurs. The rotational speed of the electric motor 30 increases rapidly immediately after the start of rotation. Thereby, the rotation speed detection signal rises with a relatively steep slope immediately after the start of rotation of the electric motor 30. On the other hand, the torque of the electric motor 30 is smaller than when no slip occurs, and as a result, the rise of the motor torque detection signal is relatively gradual.

  As shown in FIG. 3 (c), when slip occurs on the front wheel 21 while the battery-assisted bicycle 1 is traveling, the load on the electric motor 30 is reduced at the start of the slip, so that the rotational speed is immediately after the start of the slip. It rises with a relatively steep slope. As a result, an inflection point that changes in the direction in which the signal level increases appears in the rotation speed detection signal. On the other hand, the torque of the electric motor 30 decreases with a relatively steep slope immediately after the start of slipping, and an inflection point appears in the direction in which the signal level decreases in the motor torque detection signal.

  As described above, when the front wheel 21 slips during starting and running, the motor torque detection signal output from the motor torque detection unit 45 and the rotation speed detection signal output from the motor rotation speed detection unit 46 are detected. The waveform is different from that when no slip occurs. The MCU 50 samples the motor torque detection signal output from the motor torque detection unit 45 and the rotation speed detection signal output from the motor rotation number detection unit 46 at a predetermined sampling period (for example, 1 msec) and observes these signal waveforms. By doing so, the slip of the front wheel 21 is detected.

  FIGS. 4A and 4B are diagrams illustrating a method in which the MCU 50 detects a slip of the front wheel 21 when the battery-assisted bicycle 1 is started. FIG. 4A shows a time transition of the motor torque detection signal when the battery-assisted bicycle 1 starts, and FIG. 4B shows a time transition of the rotation speed detection signal when the battery-assisted bicycle 1 starts. It is shown. In each figure, the case where slip does not occur is indicated by a broken line, and the case where slip occurs is indicated by a solid line. Also, the plots in each figure show the sampling points of each signal in the MCU 50.

The MCU 50 detects the start of the battery-assisted bicycle 1 when the input torque is applied from the state where the vehicle speed is substantially zero. Here, the vehicle speed is substantially zero means that the vehicle speed at the time of starting from a state where the battery-assisted bicycle 1 is completely stopped or pushed and walked (for example, a range of about 0 to 5 km / h). Say. The same applies hereinafter. In addition, the MCU 50 can detect the vehicle speed based on, for example, the rotation speed detection signal supplied from the motor rotation speed detection unit 46. MCU50 is increased variation in the direction of the signal value of the motor torque detection signal sampled immediately after the detection of the starting of the motor-assisted bicycle 1 (increment) Delta] t ₁ is smaller than a predetermined threshold value t _s, and motor-assisted bicycle When the change amount (increase amount) Δr ₁ in the increasing direction of the signal value of the rotation speed detection signal sampled immediately after the detection of the start of ₁ is larger than a predetermined threshold, the front wheel 21 is slipped. Is determined. FIG. 4A and FIG. 4B illustrate a case where slip detection is performed using the signal value at the first sampling point and the signal value at the second sampling point after the start of the battery-assisted bicycle 1 is detected. Has been. Note that slip detection may be performed using two or more sampling points immediately after detection of the start of the battery-assisted bicycle 1. Further, the threshold values of the change amount Δt ₁ and the change amount Δr ₁ may be changed according to the input torque signal output from the input torque detection unit 42.

  FIGS. 5A and 5B are diagrams illustrating a method in which the MCU 50 detects the slip of the front wheel 21 when the battery-assisted bicycle 1 is traveling. FIG. 5A shows a time transition of the motor torque detection signal when the battery-assisted bicycle 1 is traveling, and FIG. 5B shows a time transition of the rotation speed detection signal when the battery-assisted bicycle 1 is traveling. It is shown. In each figure, the case where slip does not occur is indicated by a broken line, and the case where slip occurs is indicated by a solid line. Also, the plots in each figure show the sampling points of each signal in the MCU 50.

For example, the MCU 50 can detect the vehicle speed based on the rotation speed detection signal supplied from the motor rotation speed detection unit 46, and thus detects that the battery-assisted bicycle is running based on the rotation speed detection signal. can do. When the MCU 50 detects that the battery-assisted bicycle 1 is traveling, the inflection point where the signal value of the sampled motor torque detection signal changes and the signal value of the sampled rotation speed detection signal are detected. When an inflection point that changes in the direction in which the wheel speed increases appears at the same time, it is determined that the front wheel 21 is slipping. For example, the MCU 50 has a change amount Δt ₂ that changes in a direction in which the signal value of the motor torque detection signal decreases with respect to the previously sampled signal value is larger than a predetermined threshold, and the sampled rotation speed detection signal has a signal value of If the amount of change Δr ₂ that changes in the upward direction with respect to the previously sampled signal value is larger than a predetermined threshold value, it may be determined that the front wheel 21 is slipping.

  FIG. 6 is a flowchart showing a flow of processing in the slip detection processing program executed in the MCU 50. The program is stored in advance in a nonvolatile memory (not shown) formed in the MCU 50.

  In step S <b> 1, the MCU 50 samples signal values of the motor torque detection signal output from the motor torque detection unit 45 and the rotation speed detection signal output from the motor rotation number detection unit 46.

  In step S2, the MCU 50 determines whether or not the battery-assisted bicycle 1 is currently in a starting state. For example, the MCU 50 detects the start of the battery-assisted bicycle 1 when input torque is applied from a state where the vehicle speed is substantially zero. If the MCU 50 detects a start, the process proceeds to step S3. Otherwise, the process proceeds to step S4.

In step S3, the MCU 50 has a change amount (increase amount) Δt ₁ of the signal value of the motor torque detection signal sampled in the current step S1 with respect to the signal value of the motor torque detection signal sampled last time smaller than a predetermined threshold value t _s1 ( Δt ₁ <t _s1 ), and the change amount (increase amount) Δr ₁ of the signal value of the rotation speed detection signal sampled in the current step S1 with respect to the signal value of the rotation speed detection signal sampled last time is greater than a predetermined threshold value r _s1. It is determined whether it is large (Δr ₁ > r _s1 ). The MCU 50 proceeds to step S6 if an affirmative determination is made in step S3, and ends the present routine if a negative determination is made.

  On the other hand, in step S4, the MCU 50 determines whether or not the battery-assisted bicycle 1 is currently running. For example, the MCU 50 can detect the vehicle speed based on the rotation speed detection signal supplied from the motor rotation speed detection unit 46, and thus detects that the battery-assisted bicycle is running based on the rotation speed detection signal. can do. If the MCU 50 detects that the battery-assisted bicycle 1 is running, the process proceeds to step S5. Otherwise, the routine is terminated.

In step S5, the MCU 50 has an inflection point that changes in the direction in which the signal value of the motor torque detection signal decreases, and an inflection point that changes in the direction in which the signal value of the rotation speed detection signal increases. Determine whether or not. For example, the change amount (decrease amount) Δt ₂ of the signal value of the motor torque detection signal sampled in the current step S1 with respect to the signal value of the motor torque detection signal sampled last time is larger than a predetermined threshold value _ts2 and is sampled last time. By determining whether or not the change amount (increase amount) Δr ₂ of the signal value of the rotation speed detection signal sampled in the current step S1 with respect to the signal value of the rotation speed detection signal is larger than a predetermined threshold value r _s2 , The appearance of an inflection point may be determined. The MCU 50 proceeds to step S6 if an affirmative determination is made in step S5, and ends the present routine if a negative determination is made.

  In step S6, the MCU 50 determines that slip has occurred in the front wheels 21, sets the slip detection flag, and ends this routine.

  Thus, the MCU 50 detects the slip of the front wheel 21 with a different algorithm depending on whether the battery-assisted bicycle 1 is in a starting state or is running. Further, the MCU 50 detects the slip of the front wheel 21 based on the waveforms of both the motor torque detection signal and the rotation speed detection signal. According to such a slip detection method, reliable and quick slip detection can be realized. Moreover, according to such a slip detection method, it is possible to perform slip detection using existing components, and it is not necessary to add a component that is used only for performing slip detection. That is, a simpler configuration can be achieved than when slip is detected according to the difference in rotational speed between the front wheels and the rear wheels.

<Slip elimination processing>
Below, the slip cancellation process performed in MCU50 is demonstrated. When the MCU 50 detects a slip of the front wheel 21 in the slip detection process described above, the MCU 50 executes a slip cancellation process for eliminating the slip generated on the front wheel 21.

  FIG. 7A and FIG. 7B illustrate the time transition of the assist ratio in the electric motor 30 when the slip of the front wheel 21 is detected and the slip elimination process is executed. The plots in FIG. 7A and FIG. 7B show the output timing of the motor output command value supplied from the MCU 50 to the motor drive circuit 44. The MCU 50 issues a motor output command value at a predetermined cycle (for example, 1 msec). The assist ratio in the electric motor 30 is controlled by a motor output command value issued from the MCU 50.

  As shown in FIGS. 7A and 7B, when the MCU 50 detects the slip of the front wheel 21, the motor 50 supplies a motor output command value to the motor drive circuit 44 in order to reduce the assist ratio in the electric motor 30 step by step. To do. By reducing the assist ratio stepwise, the auxiliary driving force by the electric motor 30 decreases stepwise.

  FIG. 7A shows a case where the assist ratio is decreased by a certain amount when the slip of the front wheel 21 is detected. In other words, a case is shown in which the assist ratio is decreased at a constant slope. For example, when the assist ratio before slip detection is 100% (that is, the input torque due to the treading force and the auxiliary driving force due to the electric motor 30 is 1: 1), the MCU 50 performs the motor immediately after the slip of the front wheel 21 is detected. The assist ratio is reduced to 90%, for example, with the output command value. Thereafter, the MCU 50 determines whether or not the slip of the front wheel 21 has been resolved. If the slip has not been resolved, the MCU 50 further reduces the assist ratio to 80% with the next motor output command value. It is determined whether or not the slip has been eliminated. The MCU 50 repeats such processing until the slip of the front wheel 21 is eliminated. In this example, the assist ratio is reduced by 10% until the slip of the front wheel 21 is eliminated. Note that the amount of reduction in the assist ratio for each motor output command value can be changed as appropriate.

  FIG. 7B shows a case where the assist ratio is discounted from the previous value at a certain discount rate when a slip of the front wheel 21 is detected. For example, the MCU 50 sets the assist ratio to, for example, 50% of the immediately preceding value with the motor output command value immediately after the slip of the front wheel 21 is detected. Thereafter, the MCU 50 determines whether or not the slip of the front wheel 21 has been resolved. If the slip has not been resolved, the MCU 50 further sets the assist ratio to 50% of the immediately preceding value with the next motor output command value ( That is, the assist ratio is 25% at the beginning), and it is determined whether or not the slip of the front wheel 21 has been eliminated. The MCU 50 repeats such processing until the slip of the front wheel 21 is eliminated. Note that the discount rate of the assist ratio for each motor output command value can be changed as appropriate.

  FIG. 8 is a flowchart showing a flow of processing in the slip elimination processing program executed in the MCU 50. The program is stored in advance in a nonvolatile memory (not shown) formed in the MCU 50.

  In step S <b> 11, the MCU 50 lowers the immediately preceding assist ratio set value, and sets the value obtained thereby as the current assist ratio set value. For example, as shown in FIG. 7A, the MCU 50 may lower the assist ratio setting value so that the reduction width is constant, or the discount rate is constant as shown in FIG. 7B. The set value of the assist ratio may be lowered so that

  In step S <b> 12, the MCU 50 samples the signal value of the input torque detection signal output from the input torque detection unit 42.

  In step S13, the MCU 50 determines the motor output command value so that an auxiliary driving force having a magnitude obtained by multiplying the assist ratio derived in step S11 by the input torque indicated by the signal value of the input torque detection signal sampled in step S12 is obtained. Is generated and supplied to the motor drive circuit 44. In addition, you may restrict | limit so that the magnitude | size of the auxiliary drive force corresponding to the said motor output command value may become smaller than the magnitude of the auxiliary drive force corresponding to the motor output command value calculated last time.

  In step S <b> 14, the MCU 50 samples the signal values of the motor torque detection signal output from the motor torque detection unit 45 and the rotation speed detection signal output from the motor rotation speed detection unit 46.

  In step S15, the MCU 50 determines whether or not the slip of the front wheel 21 has been resolved based on the sampled values of the motor torque detection signal and the rotation speed detection signal sampled in step S13.

  Here, with reference to FIG. 9, a method for detecting the cancellation of the slip of the front wheel 21 will be described. FIG. 9 shows a time transition of the motor torque detection signal and the rotation speed detection signal when the slip of the front wheel 21 is eliminated and the grip is recovered. As shown in FIG. 9, when the slip of the front wheel 21 is eliminated and the front wheel 21 recovers the grip, the load on the electric motor 30 increases. As a result, the rotational speed of the electric motor 30 decreases with a relatively steep slope immediately after the slip is eliminated, and an inflection point that changes in the direction in which the signal level decreases appears in the rotational speed detection signal. On the other hand, the torque of the electric motor 30 increases with a relatively steep slope immediately after the slip is eliminated, and an inflection point appears in the direction in which the signal level increases in the motor torque detection signal. The MCU 50 determines that the slip of the front wheel 21 has been eliminated when the inflection point generated in these signals is detected from the sampled values of the sampled motor torque detection signal and the rotation speed detection signal.

  If the MCU 50 determines in step S15 that the slip has not been resolved, the process returns to step S11. If the MCU 50 determines that the slip has been resolved, the process proceeds to step S16. In step S16, the MCU 50 sets a slip cancellation flag and ends this routine.

  As described above, when the MCU 50 detects the slip of the front wheel 21, the MCU 50 repeatedly executes the reduction of the output of the electric motor 30 and the determination as to whether or not the slip is eliminated until the slip is eliminated. That is, the MCU 50 gradually reduces the output of the electric motor 30 until the slip is eliminated. As a result, it is possible to solve the problems in the conventional control method in which the output of the electric motor is reduced more than necessary, or the output is reduced but the slip is not solved. Further, according to the slip elimination process according to the present embodiment, the reduction of the assist ratio of the electric motor 30 can be suppressed to the minimum reduction width that can eliminate the slip, so that the auxiliary driving force by the electric motor 30 is ensured to the maximum. In addition, slip can be eliminated. Therefore, compared with the conventional battery-assisted bicycle, it is possible to improve the ride comfort of the driver when a slip occurs.

  In the present embodiment, the output ratio (torque) of the electric motor 30 is reduced in a stepwise manner to reduce the output (torque) of the electric motor 30 to eliminate the slip. The upper limit value may be lowered in a stepwise manner as shown in FIGS. 7 (a) and 7 (b). As a result, even when slip is detected in the process of increasing the input torque (stepping force), the output of the electric motor 30 does not increase during the slip elimination process, so the output of the motor can be quickly reduced. . In the present embodiment, the output (torque) of the electric motor 30 is reduced stepwise by decreasing the assist ratio stepwise. However, the output of the electric motor 30 (decreasing the assist ratio continuously) (Torque) may be continuously reduced. That is, the MCU 50 is configured to output the motor output command value so that the output (torque) of the electric motor 30 gradually decreases during the period from the detection of the occurrence of the slip of the front wheel 21 to the determination of the cancellation of the slip. It only has to be done.

<Motor output recovery processing>
Below, the motor output recovery process performed in MCU50 is demonstrated. When the MCU 50 determines that the slip of the front wheel 21 has been eliminated in the above-described slip elimination process, the MCU 50 executes a motor output recovery process for recovering the motor output reduced in the slip elimination process.

  An example of the motor output recovery process is shown in FIG. FIG. 10A illustrates the time transition of the assist ratio during the motor output recovery process. Each plot in FIG. 10A shows the output timing of the motor output command value supplied from the MCU 50 to the motor drive circuit 44. As shown in FIG. 10A, when the MCU 50 detects the cancellation of the slip of the front wheel 21 in the slip cancellation process, the MCU 50 generates a motor output command value to gradually increase the assist ratio in the electric motor 30 to a predetermined value. To do. For example, the MCU 50 determines the cancellation of the slip of the front wheel 21 and then increases the assist ratio by, for example, 1% by a motor output command value generated at a predetermined cycle (for example, 1 msec). For example, the assist ratio is restored to a standard assist ratio before slip detection. As described above, the output (torque) of the electric motor 30 is gradually increased by gradually increasing the assist ratio, so that the recurrence of the slip can be prevented.

  FIG. 10A shows a case where the output of the electric motor 30 is recovered by stepping up the assist ratio with a constant gradient in the motor output recovery process. However, the upper limit of the torque of the electric motor 30 is shown. The output of the electric motor 30 may be recovered by raising the value stepwise with a constant slope.

  Further, it is determined whether or not a slip has occurred in the front wheel 21 at each stage when the assist ratio is raised step by step. If a slip is detected, the assist ratio is increased by one time than before. It may be small. In addition, when slip is detected while the assist ratio is being raised stepwise, the assist ratio is lowered by executing the slip cancellation process again, and when slip cancellation is detected, You may make it raise an assist ratio again.

Another example of the motor output recovery process is shown in FIG. FIG. 10B illustrates the time transition of the torque upper limit value of the electric motor 30 during the motor output recovery process. The plot in FIG. 10B shows the output timing of the motor output command value supplied from the MCU 50 to the motor drive circuit 44. As shown in FIG. 10B, the MCU 50 sets a predetermined upper limit value _Tmax for the torque of the electric motor 30 after detecting the cancellation of the slip of the front wheel 21 by the above-described slip cancellation processing. The torque upper limit value of the electric motor 30 is increased stepwise until T _max is reached. The torque upper limit value T _max is set to a value lower than the normal torque upper limit value when no slip is detected. In this way, by setting the torque upper limit value _Tmax , even when the input torque (stepping force) is large, the torque of the electric motor 30 will not exceed the upper limit value _Tmax , so that the recurrence of slip can be prevented. it can. The output limitation of the electric motor 30 by the torque upper limit value _Tmax is released when, for example, a predetermined time (about several seconds) has elapsed or when the number of times the pedal 27 is depressed reaches a predetermined number. Is preferred.

  FIG. 11 is a flowchart showing the flow of processing in a travel control program that is executed by the MCU 50 and includes the above-described slip detection processing, slip cancellation processing, and motor output recovery processing as subroutines. The program is executed, for example, at the timing when the entire motor control system shown in FIG. 2 is started by operating a power switch (not shown) of the operation / display unit 43.

  In step S101, the MCU 50 executes the slip detection process (see FIG. 6). In step S102, the MCU 50 determines whether or not the slip detection flag is set. If the MCU 50 determines that the slip detection flag is set, the process proceeds to step S103. If the MCU 50 determines that the slip detection flag is not set, the process returns to step S101. In step S103, the MCU 50 executes the slip elimination process (see FIG. 8). In step S104, the MCU 50 determines whether or not the slip cancellation flag is set. If the MCU 50 determines that the slip cancellation flag is set, the process proceeds to step S105. In step S105, the MCU 50 executes the above-described motor output recovery process (see FIG. 10), and this routine ends.

  As apparent from the above description, according to the battery-assisted bicycle 1 according to the embodiment of the present invention, the slip of the front wheel 21 is detected based on the time transition of both the motor torque detection signal and the rotation speed detection signal. Reliable and quick slip detection can be realized. In addition, since slip detection can be performed using existing components, a slip detection system can be constructed at a low cost. Further, since the slip of the front wheel 21 is detected by a different algorithm depending on whether the host vehicle is in a starting state or traveling, more accurate slip detection can be realized.

  Further, according to the battery-assisted bicycle 1 according to the embodiment of the present invention, when the slip of the front wheel 21 is detected, the assist ratio of the electric motor 30 is decreased stepwise until the elimination of the slip is detected. Since the output is lowered step by step, it is possible to solve the problems in the conventional control method that the output of the electric motor is lowered more than necessary or the slip is not eliminated because the output is not sufficiently lowered. Further, since the amount of decrease in the output of the electric motor 30 is suppressed to a minimum magnitude that can eliminate the slip, it is possible to eliminate the slip while ensuring the maximum auxiliary driving force by the electric motor 30. As described above, according to the electric bicycle 1 according to the present embodiment, the assist function is exhibited to the maximum even when the front wheel 21 slips. Therefore, the slip occurs compared to the conventional battery-assisted bicycle. In this case, the ride comfort of the driver can be improved.

Further, according to the battery-assisted bicycle 1 according to the embodiment of the present invention, since the motor output recovery process is executed immediately after the cancellation of the slip is determined, the auxiliary driving force by the electric motor 30 can be quickly recovered. it can. Further, in the motor output recovery process, the assist ratio is increased stepwise so that the output of the electric motor 30 gradually increases, so that the recurrence of slip can be prevented. Further, according to the motor output recovery process according to another aspect, the upper limit value _Tmax is set for the torque of the electric motor 30 and the driving force of the front wheels 21 is limited, so that the recurrence of the slip can be prevented.

[Second Embodiment]
Hereinafter, a battery-assisted bicycle according to the second embodiment of the present invention will be described. In the battery-assisted bicycle according to the second embodiment, the MCU 50 determines the slipperiness of the road surface or the scale of the slip based on the motor torque detection unit signal and the rotation speed detection signal in the slip detection process described above. The assist ratio reduction amount or the discount rate in the slip elimination process is changed according to the slipperiness of the road surface or the size of the slip. Furthermore, in the battery-assisted bicycle according to the second embodiment, the MCU 50 changes the motor output recovery mode in the motor output recovery process according to the determined slipperiness of the road surface or the magnitude of the slip.

  First, a method in which the MCU 50 determines the slipperiness of the road surface or the slip scale in the slip detection process will be described. Also in the battery-assisted bicycle according to the present embodiment, the slip of the front wheel 21 is detected based on the motor torque detection signal and the rotation speed detection signal as in the first embodiment.

Here, as shown in FIG. 4, when a slip occurs on the front wheels 21 when the battery-assisted bicycle starts, the motor torque detection signal rises more slowly than when no slip occurs. On the other hand, the rise of the rotation speed detection signal is steep compared to the case where no slip occurs. The difference between the waveform when such slip occurs and the waveform when no slip occurs becomes more prominent as the road surface becomes slippery. That is, when the road surface is more slippery (when the friction coefficient of the road surface is smaller), the change amount Δt ₁ between the sampling points of the motor torque detection signal shown in FIG. The amount of change Δr ₁ between the sampling points of the rotation speed detection signal shown in 4 (b) becomes larger. Accordingly, the MCU 50 detects the slip of the front wheel 21 at the time of starting based on the waveforms of the motor torque detection signal and the rotation speed detection signal, and detects the changes Δt ₁ and Δr ₁ between the sampling points of these signals. Thus, the slipperiness of the road surface or the scale of the slip can be determined. The MCU 50 classifies the slipperiness of the currently running road surface or the magnitude of the slip into, for example, one of three ranks (A, B, C) according to the magnitudes of the changes Δt ₁ and Δr _1. . At this time, ranking may be performed in consideration of the magnitude of the input torque. Note that the degree of slipperiness of the road surface or the scale of the slip may be ranked in accordance with both and _one of the change amounts Δt ₁ and Δr ₁ .

On the other hand, as shown in FIG. 5, when a slip occurs during the traveling of the battery-assisted bicycle, an inflection point appears in both the motor torque detection signal and the rotation speed detection signal. Inflection points generated in these signal waveforms become more prominent as the road surface becomes slippery. That is, as the road surface is more slippery, the level difference Δt ₂ and Δr between the signal value at the sampling point corresponding to the inflection point and the signal value at the sampling point immediately after the inflection point (sampling point corresponding to the slip detection point). ₂ becomes larger. Therefore, the MCU 50 detects the slip of the front wheel 21 during traveling based on the waveforms of the motor torque detection signal and the rotation speed detection signal, and the signal value between the inflection point of these signals and the slip detection point. By detecting the change amounts Δt ₂ and Δr ₂ , the slipperiness of the road surface or the scale of the slip can be determined. The MCU 50 classifies the slipperiness of the currently running road surface or the magnitude of the slip into, for example, one of three ranks (A, B, C) according to the magnitudes of the changes Δt ₂ and Δr _2. . At this time, ranking may be performed in consideration of the magnitude of the input torque. Note that the slipperiness of the road surface or the scale of the slip may be ranked according to both and one of the change amounts Δt ₂ and Δr ₂ .

FIG. 12 is a flowchart showing the flow of processing in the slip detection processing program according to the second embodiment of the present invention, including the determination processing of the slipperiness of the road surface or the scale of slip. The processing in steps S21 to S26 in this flowchart is the same as steps S1 to S6 in the flowchart shown in FIG. In step S27, MCU 50, the change amount of the motor torque detection signal at the time of starting Delta] t ₁ and the amount of change in the rotational speed detection signal [Delta] r ₁ or the change of the amount of change Delta] t ₂ and the rotational speed detection signal of the motor torque detection signal during travel Based on the amount Δr ₂ , the slipperiness or the magnitude of the slip on the currently running road is ranked, for example, in one of three ranks (A, B, C). Here, A rank, B rank, and C rank are set in order of easy slipping. The MCU 50 stores the ranking result in the memory, and this routine ends.

  Next, an aspect in which the MCU 50 changes the assist ratio reduction amount or reduction rate in accordance with the slipperiness of the road surface or the rank of the slip scale in the slip elimination processing will be described.

  FIG. 13A is a diagram exemplifying a case where the assist ratio reduction width is changed in accordance with the slipperiness of the road surface or the scale of the slip in the slip elimination processing. In the slip detection process, the MCU 50 determines that the slipperiness of the currently running road surface or the scale of the slip is C rank, as shown by a one-dot chain line in FIG. Make the pull-down width relatively small. That is, the assist ratio is lowered with a relatively small inclination. On the other hand, when the MCU 50 determines that the slipperiness or the magnitude of the slip on the currently running road is rank A, as shown by the broken line in FIG. To be large. That is, the assist ratio is lowered with a relatively large inclination. On the other hand, if the MCU 50 determines that the slipperiness or slippage of the currently running road surface is rank B, as shown by the solid line in FIG. To the extent. That is, the assist ratio is lowered by an intermediate slope between the slope in the A rank and the slope in the C rank.

  FIG. 13B is a diagram exemplifying a case where the discount rate of the immediately preceding assist ratio is changed according to the slipperiness of the road surface or the scale of the slip. In this case, in the slip detection process, when the slip detection process determines that the slipperiness of the currently running road surface or the scale of the slip is C rank, the MCU 50 immediately preceding assists as shown by a one-dot chain line in FIG. The discount rate for the ratio is relatively small. For example, the MCU 50 repeats the process of setting the assist ratio to 80% of the previous value (discount rate 20%) until the slip is resolved. On the other hand, when the MCU 50 determines that the slipperiness or the magnitude of the slip on the currently running road is A rank, the MCU 50 relatively reduces the discount rate for the immediately preceding assist ratio as shown by the broken line in FIG. Great. For example, the MCU 50 repeats the process of setting the assist ratio to 40% of the previous value (discount rate 60%) until the slip is resolved. On the other hand, when the MCU 50 determines that the slipperiness or the magnitude of the slip on the currently running road is B rank, the discount rate with respect to the immediately preceding assist ratio is medium as shown by the solid line in FIG. And For example, the MCU 50 repeats the process of setting the assist ratio to 60% of the previous value (discount rate 40%) until the slip is resolved.

  In the case of a C-rank road surface that is relatively difficult to slip, it is considered that the slip is eliminated if the driving force of the front wheels 21 is slightly reduced. Therefore, it is possible to eliminate the slip while securing the assist ratio to the maximum by reducing the one-time reduction width or the discount rate of the assist ratio in the slip elimination process.

  On the other hand, in the case of an A rank road surface that is very slippery, it is highly likely that the slip will not be resolved even if the driving force of the front wheels 21 is slightly reduced. Accordingly, it is possible to quickly eliminate the slip by increasing the one-time reduction ratio or discount rate of the assist ratio in the slip cancellation process.

  FIG. 14 shows a second embodiment of the present invention in which the assist ratio is reduced stepwise by determining the reduction width or discount rate of the assist ratio according to the determination result of the slipperiness of the road surface or the scale of the slip. It is a flowchart which shows the flow of a process in a slip cancellation processing program.

  In step S31, the MCU 50 reads from the memory the slipperiness of the road surface or the rank of the scale of the slip stored in the memory in step S27 of the slip detection process.

  In step S32, the MCU 50 refers to the table in which the rank of the slipperiness of the road surface or the scale of the slip and the reduction ratio or discount rate of the assist ratio are associated with each other, and the reduction ratio of the assist ratio corresponding to the read rank. Or determine the discount rate.

  In step S33, the MCU 50 lowers the previous assist ratio set value by the reduction amount or discount rate determined in step S32, and sets the value obtained thereby as the current assist ratio set value. .

  The subsequent processes in steps S34 to S38 are the same as steps S12 to S16 of the slip elimination process according to the first embodiment described above, and thus the description thereof is omitted.

  As described above, according to the battery-assisted bicycle according to the present embodiment, the assist ratio reduction width or the discount rate in the slip elimination process increases as the road surface easily slips. That is, when a slip occurs in a relatively slippery road surface condition, the assist ratio decreases quickly, so that the time from slip detection to slip cancellation can be further shortened. On the other hand, when a slip occurs in a road surface condition that is relatively difficult to slip, the assist ratio gradually decreases, so that it is possible to eliminate the slip while ensuring the auxiliary driving force.

  In the above description, the MCU 50 determines the slipperiness of the road surface or the magnitude of the slip from the waveforms of the motor torque detection signal and the rotation speed detection signal when the front wheel 21 slips, and determines the slipperiness or slippage of the determined road surface. Although the case where the reduction ratio or the discount rate of the assist ratio is set according to the scale is illustrated, the present invention is not limited to this. That is, the MCU 50 detects a change in the slip size of the front wheel 21 during the slip elimination process, and changes the assist ratio reduction width or discount rate from the previous reduction rate or discount rate according to the result of the slip size. Good.

  In this case, the MCU 50 monitors the motor torque detection signal output from the motor torque detection unit 45 during the slip elimination process, and determines the change in the scale of the slip based on the change in the signal level. The torque of the electric motor 30 increases as the size of the slip generated on the front wheel 21 decreases as a result of the slip elimination process. Therefore, the MCU 50 can detect the change in the scale of the slip after the occurrence of the slip based on the amount of change in the signal level of the motor torque detection signal after the occurrence of the slip of the front wheel 21 in the slip elimination process. Note that the MCU 50 may use the rotation speed detection signal in combination with the detection of the change in the slip scale.

  In the slip elimination process, the MCU 50 samples the motor torque detection signal at each stage of gradually reducing the motor output, detects a change in the slip scale, and determines that the slip scale has become smaller (that is, the motor 50 When the signal level of the torque detection signal is increased), the motor output command value is generated so that the assist ratio reduction rate or discount rate is smaller than the previous value or is maintained. . On the other hand, when the MCU 50 determines that the magnitude of the slip has not changed or has increased (that is, when the signal level of the motor torque detection signal has not changed or has decreased), the assist ratio reduction range and the discount rate are reduced. A motor output command value is generated so as to be larger than the previous value.

For example, as shown in FIG. 15, when the signal level a _{0 at} an arbitrary sampling point SP1 of the motor torque detection signal is increased to a ₁ at the next sampling point SP2 during the slip elimination process, the MCU 50 It is determined that the size of the slip has become smaller, and the assist ratio reduction width or discount rate in the slip elimination processing is set to be smaller than the immediately preceding reduction width or discount rate.

On the other hand, during the slip resolving process, MCU 50 may signal level of the motor torque detection signal is increased from a ₀ to a _2, which assists the ratio of Decrement the determination to slip resolving process as scale of slip becomes smaller Alternatively, the discount rate is set to be smaller than the previous value. However, since the reduction amount of the slip scale is smaller than that in the case of changing from a ₀ to a ₁ as described above, the MCU 50 reduces the reduction amount with respect to the value immediately before the reduction ratio or discount rate of the assist ratio from the above a ₀ to a. _It is smaller than the case of changing to ₁ . Thus, the MCU 50 quantitatively detects the amount of change in the slip scale from the amount of change in the signal level of the motor torque detection signal, and the greater the amount of reduction in the slip scale (that is, the signal level of the motor torque detection signal). The larger the increase amount), the smaller the assist ratio reduction amount or the discount rate immediately before the discount rate or discount rate is reduced. If the increase in the signal level of the motor torque detection signal is less than the predetermined value during the slip cancellation process, the assist ratio reduction or discount rate is set to the same value as the previous reduction or discount rate. May be.

  On the other hand, if the signal level of the motor torque detection signal does not change during the slip elimination process, the MCU 50 determines that the scale of the slip does not change, and makes the assist ratio reduction range or discount rate larger than the previous value. Set as follows.

On the other hand, during the slip resolution processing, when the signal level of the motor torque detection signal is lowered from a ₀ to a ₃ are, MCU 50 is the assist ratio in the determination to slip resolving process as scale of the slip became larger The amount of reduction or discount rate is set to be larger than the previous value, but the slip size is large, so the amount of increase in the assist ratio reduction amount or discount rate immediately before the reduction amount or discount rate is the slip size. Larger than when there is no change.

  In this way, the assist ratio reduction or discount rate increases as the slip scale increases by successively changing the assist ratio reduction or discount rate so as to follow the change in slip size during the slip elimination process. Therefore, the time until the slip is eliminated can be minimized. On the other hand, as the slip scale decreases, the assist ratio reduction or discount rate decreases, so the assist ratio at the time of slip cancellation can be maximized.

  Next, an aspect in which the MCU 50 changes how the motor output is restored in accordance with the slipperiness of the road surface or the rank of the slip scale in the motor output recovery process will be described. As in the case of the first embodiment, the MCU 50 executes a motor output recovery process in which the output of the electric motor 30 is increased stepwise after detecting the cancellation of the slip of the front wheel 21.

  FIG. 16A is a diagram illustrating the motor output recovery process according to the present embodiment, and illustrates the time transition of the assist ratio during the motor output recovery process. In the present embodiment, in the motor output recovery process, the MCU 50 changes the inclination of raising the assist ratio according to the slipperiness of the road surface or the rank of the slip scale. Specifically, when the MCU 50 determines that the slipperiness of the currently running road surface or the scale of the slip is the C rank in the slip detection process, as shown by a one-dot chain line in FIG. The range of raising the assist ratio once is relatively large. That is, the assist ratio is increased with a relatively large inclination. On the other hand, when the MCU 50 determines that the slipperiness or the magnitude of the slip on the currently running road is A rank, as shown by a broken line in FIG. Make it small. That is, the assist ratio is increased with a relatively small inclination. On the other hand, if the MCU 50 determines that the slipperiness or the magnitude of the slip on the currently running road surface is B rank, as shown by the solid line in FIG. To the extent. That is, the assist ratio is increased by an intermediate slope between the slope in the A rank and the slope in the C rank. As described above, by changing the inclination of the increase in the assist ratio according to the slipperiness of the road surface or the scale of the slip, it is possible to realize appropriate power assist according to the slipperiness of the road surface or the scale of the slip.

FIG. 16B is a diagram illustrating another example of the motor output recovery process according to the present embodiment, and illustrates the time transition of the upper limit value of the torque of the electric motor 50 during the motor output recovery process. As shown in FIG. 16B, after detecting the cancellation of the slip of the front wheel 21, the MCU 50 differs in the upper limit value of the torque of the electric motor 30 according to the slipperiness of the road surface or the rank of the slip scale. It may be set to a value. Specifically, when the MCU 50 determines that the slipperiness of the currently running road surface or the scale of the slip is the C rank in the slip detection process, as shown by the alternate long and short dash line in FIG. Then, the torque upper limit value of the electric motor 30 is set to a relatively large T _max1 , and the torque upper limit value of the electric motor 30 is increased stepwise until the torque upper limit value T _max1 is reached. On the other hand, when the MCU 50 determines that the slipperiness or the magnitude of the slip on the currently running road surface is A rank, the MCU 50 sets the torque upper limit value of the electric motor 30 relatively as shown by the broken line in FIG. A small T _max3 is set, and the torque upper limit value of the electric motor 30 is increased stepwise until the torque upper limit value T _max3 is reached. On the other hand, when the MCU 50 determines that the slipperiness or the magnitude of the slip on the currently running road is rank B, the torque upper limit value of the electric motor 30 is set to T _{max1 as} shown by a solid line in FIG. _Is set to T _max2 between T _max3 and T _max3 , and the torque upper limit value of the electric motor 30 is increased stepwise until the torque upper limit value T _max2 is reached. The torque upper limit values T _max1 , T _max2 , and T _max3 are preferably set to values lower than the normal torque upper limit value when no slip is detected. The output limit of the electric motor 30 by the torque upper limit values T _max1 , T _max2 , and T _max3 is, for example, when a predetermined time (about several seconds) has elapsed, or when the number of depressions of the pedal 27 reaches a predetermined number. It may be canceled. According to such a motor output recovery process, in a situation where the road surface is slippery, the output (torque) of the electric motor 30 is sufficiently suppressed, so that the recurrence of the slip can be effectively prevented. On the other hand, in a situation where the road surface is difficult to slip, the output (torque) of the electric motor 30 is ensured to some extent, so that a sufficient auxiliary driving force can be obtained while preventing the recurrence of the slip. Accordingly, even in this case, it is possible to realize appropriate power assist in accordance with the slipperiness of the road surface or the scale of the slip.

[Third embodiment]
The battery-assisted bicycle according to the third embodiment of the present invention will be described below. In the battery-assisted bicycle according to the third embodiment of the present invention, the MCU 50 detects a slip of the front wheel 21, and there is a predetermined condition that can be determined that the currently running road surface is slippery. When established, the process shifts to a “low assist mode” in which the output of the electric motor 30 is controlled so that the assist ratio is smaller than the normal assist ratio.

  FIG. 17 is a flowchart showing a process flow in the assist mode switching process program executed in the MCU 50. The program is stored in advance in a nonvolatile memory (not shown) formed in the MCU 50. The program is executed, for example, at the timing when the entire control system shown in FIG. 2 is activated by operating a power switch (not shown) of the operation / display unit 43.

  In step S41, the MCU 50 determines whether or not a slip has occurred in the front wheel 21. The slip detection of the front wheel 21 can be performed according to the slip detection process described above (see FIG. 6). When the MCU 50 detects a slip in this step, the process proceeds to step S42. The MCU 50 may execute the slip elimination process and the motor output recovery process shown in the first embodiment and the second embodiment after detecting the slip in this step.

  In step S42, the MCU 50 determines whether or not a condition for shifting to the low assist mode is satisfied. The MCU 50, for example, when the above-described series of slip detection processing, slip cancellation processing, and motor output recovery processing is executed a predetermined number of times (for example, 3 times) within a predetermined period (for example, 5 seconds) from the first slip detection time. Alternatively, it may be determined that the condition for shifting to the low assist mode is satisfied by determining that the currently running road surface is slippery.

  Further, the MCU 50 determines that the currently running road surface is slippery when the slip of the front wheel 21 is detected in association with, for example, two successive pedal depression operations by the driver. It may be determined that the condition for shifting to the low assist mode is satisfied.

  Further, the MCU 50 relates to the front wheel 21 in relation to any one or a plurality of pedal depressions of a plurality of pedals performed within a predetermined period (for example, 10 seconds) from the first slip detection time. When the slip is detected, it may be determined that the condition for shifting to the low assist mode is satisfied. For example, the MCU 50 can detect the timing of the pedal depression operation by the driver by monitoring an input torque signal as shown in FIG. 18 that has a peak corresponding to the pedal depression operation.

  If the MCU 50 determines in step S42 that the condition for shifting to the low assist mode is satisfied, the process proceeds to step S43. If the MCU 50 determines that the condition for shifting is not satisfied, the process proceeds to step S41. return.

  In step S43, the MCU 50 shifts the assist mode from the normal mode to the low assist mode by setting the assist ratio setting value to a value smaller than the assist ratio setting value before slip detection. After shifting to the low assist mode, the MCU 50 performs auxiliary driving having a magnitude obtained by multiplying the magnitude of the input torque (stepping force) indicated by the input torque signal supplied from the input torque detection unit 42 by the assist ratio in the low assist mode. A motor output command value is generated to drive the front wheels 21 with force, and is supplied to the motor drive circuit 44.

  In step S44, the MCU 50 determines whether or not a condition for canceling the low assist mode is satisfied. For example, the MCU 50 may determine that the condition for canceling the low assist mode is satisfied when a predetermined period (for example, 10 seconds) has elapsed since the start of the shift to the low assist mode. The MCU 50 may determine that the condition for canceling the low assist mode is satisfied when the number of times the driver depresses the pedal after shifting to the low assist mode reaches a predetermined number (for example, three times). . Further, the MCU 50 may determine that the condition for canceling the low assist mode is satisfied when the travel distance after shifting to the low assist mode reaches a predetermined value. Alternatively, the MCU 50 may determine that the condition for canceling the low assist mode is satisfied when the slip of the front wheel 21 is not detected for a predetermined period (for example, 10 seconds) after the transition to the low assist mode. If the MCU 50 determines that the condition for canceling the low assist mode is satisfied, the process proceeds to step S45.

  In step S45, the MCU 50 cancels the low assist mode and switches the assist ratio of the electric motor 30 from the assist ratio in the low assist mode to the assist ratio in the normal mode before slip detection. After shifting to the normal mode, the MCU 50 uses an auxiliary driving force having a magnitude obtained by multiplying the magnitude of the input torque (stepping force) indicated by the input torque signal supplied from the input torque detector 42 by the assist ratio in the normal mode. A motor output command value is generated to drive the front wheels 21 and supplied to the motor drive circuit 44.

  As described above, according to the battery-assisted bicycle according to the present embodiment, it is determined whether or not the condition for shifting to the low assist mode is satisfied according to the slip occurrence state of the front wheels 21, and the condition for shifting to the low assist mode is satisfied. In this case, the assist ratio in the electric motor 30 is set to a value smaller than the assist ratio before the occurrence of slip. According to such assist switching control, when traveling on a relatively slippery road surface, the assist ratio is set to a smaller value than usual, so that it is possible to effectively prevent the recurrence of slip. In addition, by providing a condition for canceling the low assist mode, it is possible to return to the normal mode even when the low assist mode has been entered.

  FIG. 19 is a flowchart showing the flow of processing in the assist mode switching processing program according to the modification.

  In step S51, the MCU 50 determines whether or not a slip has occurred in the front wheel 21. The slip detection of the front wheel 21 can be performed in accordance with the slip detection process (see FIG. 12) according to the second embodiment described above. That is, in this step S51, slip detection is performed, and the slipperiness of the road surface or the scale of the slip is ranked.

  In step S52, the MCU 50 stores in the memory the slipperiness of the road surface or the rank of the magnitude of the slip.

  In step S53, the MCU 50 determines whether or not a condition for shifting to the low assist mode is satisfied. In this routine, the slipperiness of the road surface or the rank of the slip scale may be used as a condition for shifting to the low assist mode. For example, it may be determined that the transition condition to the low assist mode is satisfied when the slipperiness of the road surface or the rank of the scale of the slip is A rank. If the MCU 50 determines that the condition for shifting to the low assist mode is satisfied, the process proceeds to step S54. If the MCU 50 determines that the condition for shifting is not satisfied, the process returns to step S51.

  In step S54, the MCU 50 reads out the slipperiness of the road surface or the rank of the slip scale from the memory.

  In step S55, the MCU 50 shifts the assist mode from the normal mode to the low assist mode by setting the assist ratio of the electric motor 30 to a value smaller than the set value before slip detection. At this time, the MCU 50 sets the assist ratio in the low assist mode according to the slipperiness of the road surface read in step S54 or the rank of the slip scale. That is, when the MCU 50 determines that the road surface is relatively slippery, the MCU 50 sets the assist ratio in the low assist mode to a relatively small value. When the MCU 50 determines that the road surface is relatively difficult to slide, the MCU 50 Set the assist ratio to a relatively large value. The MCU 50 may derive the set value of the assist ratio in the low assist mode by referring to a table in which the slipperiness of the road surface or the magnitude of the slip is associated with the set value of the assist ratio.

  In step S56, the MCU 50 sets conditions for canceling the low assist mode in accordance with the slipperiness of the road surface read in step S54 or the rank of the slip scale. For example, when the release condition is defined by the elapsed time after shifting to the low assist mode, the longer the elapsed time as the release condition may be requested as the road surface slides more easily. For example, if the MCU 50 determines that the road surface is relatively slippery, the MCU 50 sets “10 seconds after shifting to the low assist mode” as a release condition, and determines that the road surface is relatively difficult to slip. , “5 seconds after transition to the low assist mode” may be set as the release condition.

  In addition, for example, when the release condition is defined by the number of pedal depressions by the driver after shifting to the low assist mode, the more the road surface is slippery, the more the number of pedal depressions as the release condition, It may be requested many times. For example, if the MCU 50 determines that the road surface is relatively slippery, the MCU 50 sets “the pedal must be depressed 5 times after shifting to the low assist mode” as a release condition, and the road surface is relatively difficult to slide. When the determination is made, “the pedal must be depressed once after shifting to the low assist mode” may be set as the release condition.

  In addition, for example, when the release condition is defined by the non-detection period of the slip of the front wheel 21 after shifting to the low assist mode, the longer the non-detection period as the slip non-detection period as the release condition, the slippery the road surface. May be requested. For example, when the MCU 50 determines that the road surface is relatively slippery, the MCU 50 sets “the non-detection period of the slip of the front wheel 21 continues for 10 seconds after shifting to the low assist mode” as a release condition, and the road surface If it is determined that it is relatively difficult to slip, “the non-detection period of the slip of the front wheel 21 continues for 3 seconds after shifting to the low assist mode” may be set as a cancellation condition.

  In step S57, the MCU 50 determines whether or not the release condition set in step S56 is satisfied. If it is determined that the release condition is satisfied, the process proceeds to step S58.

  In step S58, the MCU 50 releases the low assist mode, switches the assist ratio of the electric motor 30 from the assist ratio in the low assist mode to the assist ratio in the normal mode before slip detection, and ends this routine.

  Thus, by setting the assist ratio when shifting to the low assist mode according to the slipperiness of the road surface or the scale of the scale of the slip, it is possible to select an appropriate amount according to the slipperiness of the road surface when a slip occurs. It is possible to limit output. Furthermore, it is possible to effectively suppress the recurrence of the slip by setting the release condition of the low assist mode in accordance with the slipperiness of the road surface or the rank of the slip scale.

  In each of the above embodiments, the slip of the front wheel 21 is detected from the waveforms of the motor torque detection signal and the rotation speed detection signal. However, the slip of the front wheel 21 is determined from the rotation speed difference between the front wheel 21 and the rear wheel 22. It may be detected. In this case, the rotational speed of the front wheel 21 driven by the electric motor 30 can be calculated from the rotational speed, gear ratio, and the like of the electric motor 30. On the other hand, the rotation speed of the rear wheel 22 driven by the driver's pedal depression operation can be calculated from, for example, a known rotation detector (encoder) or a cycle of the input torque signal synchronized with the pedal depression operation. It is.

  Further, in each of the above embodiments, the case where the present invention is applied to a type of battery-assisted bicycle that drives the front wheels 21 with the electric motor 30 is illustrated, but the present invention is applied to a type of battery-assisted bicycle that drives the rear wheels with an electric motor. The invention can also be applied.

DESCRIPTION OF SYMBOLS 1 Electric assist bicycle 21 Front wheel 22 Rear wheel 30 Electric motor 31 Battery 42 Input torque detection part 44 Motor drive circuit 45 Motor torque detection part 46 Motor rotation speed detection part 50 MCU

Claims (5)

An auxiliary drive system that generates an auxiliary drive force according to an input torque by a pedaling force applied to the pedal by an electric motor, and drives a wheel by the auxiliary drive force; and
Slip occurrence detecting means for detecting occurrence of slip of the wheel;
When a slip of the wheel is detected by the slip generation detecting means, an assist ratio, which is a ratio of the magnitude of the auxiliary driving force to the magnitude of the input torque due to the pedal effort, is greater than the magnitude before the detection of the wheel slip. The output of the electric motor is controlled so that the assist ratio becomes smaller, and the number of times the pedal is depressed after the output of the electric motor is controlled so that the assist ratio becomes smaller than the magnitude before the detection of the slip of the wheel is predetermined. Control means for controlling the output of the electric motor so that the assist ratio becomes the magnitude before the detection of the slip of the wheel when the release condition is satisfied ,
Including motor-assisted bicycles. An auxiliary drive system that generates an auxiliary drive force according to an input torque by a pedaling force applied to the pedal by an electric motor, and drives a wheel by the auxiliary drive force; and
Slip occurrence detecting means for detecting occurrence of slip of the wheel;
When a slip of the wheel is detected by the slip generation detecting means, an assist ratio, which is a ratio of the magnitude of the auxiliary driving force to the magnitude of the input torque due to the pedal effort, is greater than the magnitude before the detection of the wheel slip. The output of the electric motor is controlled so that the assist ratio becomes smaller, and the output of the electric motor is controlled so that the assist ratio becomes smaller than the magnitude before the detection of the slip of the wheel. Then, when not detecting the slip of the wheel, a control means for controlling the output of the electric motor so that the assist ratio becomes the size before the detection of the slip of the wheel, assuming that the release condition is satisfied ,
Including motor-assisted bicycles. An auxiliary drive system that generates an auxiliary drive force according to an input torque by a pedaling force applied to the pedal by an electric motor, and drives a wheel by the auxiliary drive force; and
Slip occurrence detecting means for detecting occurrence of slip of the wheel;
Determining means for determining the magnitude of slip generated in the wheel;
When a slip of the wheel is detected by the slip generation detecting means, an assist ratio, which is a ratio of the magnitude of the auxiliary driving force to the magnitude of the input torque due to the pedal effort, is greater than the magnitude before the detection of the wheel slip. The output of the electric motor is controlled so that the assist ratio from the detection of the wheel slip until the predetermined release condition is satisfied decreases as the slip size determined by the determination means increases. and control means for controlling an output of the electric motor as the assist ratio becomes a magnitude of the previous detection of the slip of the wheels when said predetermined cancellation condition is satisfied,
Including motor-assisted bicycles. A judgment means for judging a magnitude of slip generated in the wheel;
Wherein, the larger the scale of the slip determined by the determining means, after the detection of the slip of the wheel according to claim 1 or claim 2 to reduce the assisting ratio to the release condition is satisfied Electric assist bicycle. The control means, the motor-assisted bicycle according to claim 3 or claim 4 to change the pre Machinery removal conditions depending on the size of the slip determined by the determining means.

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