JP7122700B2 - Electric bicycle - Google Patents

Description

The present invention relates to electric bicycles.

2. Description of the Related Art Conventionally, an electric bicycle has been disclosed that includes an electric motor and is capable of exerting an auxiliary driving force of the electric motor when walking (for example, see Patent Document 1). According to this electric bicycle, it is possible for the user to operate the push-walking operation means of the electric bicycle to obtain auxiliary driving force from the electric motor during push-walking.

Japanese Patent No. 4118985

By the way, in an electric bicycle equipped with a push-walking mode, the user operates the push-walking operation means to generate an auxiliary driving force and accelerate the electric bicycle to a predetermined speed. Therefore, even when the user is riding the electric bicycle, if the push-walking operation means is operated, an auxiliary driving force for push-walking will be generated.

SUMMARY OF THE INVENTION An object of the present invention is to provide an electric bicycle that does not generate an auxiliary drive force for pushing while the user is riding the electric bicycle.

In order to achieve the above object, an electric bicycle according to one aspect of the present invention is an electric bicycle including an electric motor, in which a first auxiliary driving force by the electric motor is added to a human-powered driving force based on a force applied to a pedal. and a second mode in which the vehicle is pushed by adding a second auxiliary driving force to the vehicle body by the electric motor, or a second mode in which the vehicle is self-propelled by adding the second auxiliary driving force. a control unit that receives an operation for executing the second mode; a saddle on which the user sits, a normal posture in which the seat surface of the saddle is in a normal position; a saddle that can be switched between a non-normal posture away from the position of the control unit, the operation unit executes the second mode when the operation unit receives the operation, and the operation unit performs the second mode when the saddle is in the normal posture It is hidden and located where it is exposed when the saddle is in an irregular position.

According to the present invention, it is possible to provide an electric bicycle that does not generate auxiliary driving force for pushing while the user is riding the electric bicycle.

FIG. 1 is a side view showing an electric bicycle according to an embodiment. FIG. FIG. 2 is a perspective view of a handle and an operating portion of the electric bicycle according to the embodiment. FIG. 3 is a side view showing the electric bicycle according to the embodiment when the saddle is in an irregular posture. FIG. 4 is a perspective view showing the switching portion in the normal posture according to the embodiment. FIG. 5 is a cross-sectional perspective view showing the switching portion in the normal posture according to the embodiment. FIG. 6 is a perspective view showing a switching portion in an irregular posture according to the embodiment. FIG. 7 is a cross-sectional perspective view showing the switching portion in an irregular posture according to the embodiment. FIG. 8 is a block diagram showing the configuration of the electric bicycle according to the embodiment. FIG. 9 is a flow chart showing the flow of the electric bicycle control method according to the embodiment. 10 is a side view showing an electric bicycle according to Modification 1. FIG. FIG. 11 is a perspective view showing a switching unit in an irregular posture according to Modification 2. FIG.

BEST MODE FOR CARRYING OUT THE INVENTION Below, embodiments of the present invention will be described in detail with reference to the drawings. It should be noted that each of the embodiments described below is a specific example of the present invention. Therefore, the numerical values, shapes, materials, components, arrangement and connection of components, steps, order of steps, etc. shown in the following embodiments are examples and are not intended to limit the present invention. Therefore, among the constituent elements in the following embodiments, constituent elements that are not described in independent claims representing the highest level concept of the present invention will be described as optional constituent elements.

Each figure is a schematic diagram and is not necessarily strictly illustrated. Therefore, for example, scales and the like do not necessarily match in each drawing. Moreover, in each figure, the same code|symbol is attached|subjected about the substantially same structure, and the overlapping description is abbreviate|omitted or simplified.

In the following description, "forward" is the direction in which the electric bicycle travels, and "backward" is the opposite direction. Specifically, the handle side is "forward" with respect to the saddle of the electric bicycle. A “left-right direction” is a direction perpendicular to the front-rear direction.

[Constitution]
First, the configuration of the electric bicycle 1 according to the embodiment will be described. FIG. 1 is a side view showing an electric bicycle 1 according to an embodiment.

The electric bicycle 1 has a first mode and a second mode. The first mode is, for example, an assist mode, and assists forward movement of the vehicle body 10 based on the user's stepping force on the pedal 17 . The second mode includes, for example, a push-walk mode or a free-running mode. In the push-walking mode, when the user walks while pushing the electric bicycle 1, forward movement of the vehicle body 10 is assisted based on the user's force pushing the vehicle body 10 forward. In the self-propelled mode, the forward movement of the vehicle body 10 is assisted while the electric bicycle 1 is being supported.

The electric bicycle 1 includes a vehicle body 10, a motor drive unit 20 attached to the vehicle body 10, an operation unit 40, a battery 50, a headlight 60, a crank rotation sensor 31, a pedaling force sensor 33, and a current sensor 130. , a vehicle speed sensor 243 , and a shift stage measuring unit 70 .

The vehicle body 10 includes a frame 11, front wheels 12, rear wheels 13, a steering wheel 14, a saddle 15, cranks 16, pedals 17, sprockets 18 and chains 19. - 特許庁

The frame 11 includes a head pipe 111 , a main frame 112 , a standing pipe 113 , a fork 114 and chain stays 115 . The head pipe 111 supports a fork 114 supporting the front wheel 12 and a handle 14 so as to be rotatable around the axis of the head pipe 111 . By turning the handle 14 left and right, the direction of the front wheel 12 supported by the fork 114 can be turned left and right.

The main frame 112 is a portion that connects the head pipe 111 and the standing pipe 113 . A crank 16 and a motor drive unit 20 are attached to the lower end of the main frame 112 . The electric bicycle 1 according to the present embodiment is a so-called center unit type electric bicycle 1 in which the crank 16 and the motor drive unit 20 are integrated.

The standing pipe 113 detachably supports the saddle 15 . Specifically, a seat post 151 that supports the saddle 15 is inserted and fixed to the standing pipe 113 . In this embodiment, the battery 50 is detachably attached to the standing pipe 113 .

The fork 114 rotatably supports the front wheel 12 . A headlamp 60 is attached to the fork 114 that supports the front wheel 12 . Chain stay 115 rotatably supports rear wheel 13 .

FIG. 2 is a perspective view of the handle 14 and the operating portion 40 of the electric bicycle 1 according to the embodiment. As shown in FIG. 2, the handle 14 is provided with a pair of grips 141 and brake levers 142 on the left and right. A pair of grips 141 are portions that are gripped by a hand when the user gets on the vehicle in an appropriate posture. Also, the pair of grips 141 are gripped by the hand when the user pushes or supports the electric bicycle 1 and receives a forward pushing force. At least one of the pair of grips 141 may be provided with a grip sensor that detects gripping force or pressing force.

A pair of brake levers 142 are operation levers of a brake device (not shown) attached to each of the front wheel 12 and the rear wheel 13 . When the user operates one of the brake levers 142 , the brake device attached to the front wheels 12 is driven to apply mechanical braking force to the front wheels 12 . When the user operates the other brake lever 142 , the brake device attached to the rear wheel 13 is driven to apply a mechanical braking force to the rear wheel 13 .

An operation unit 40 is provided near one of the pair of brake levers 142 (the left brake lever 142 in this embodiment). The operation unit 40 is a terminal device including a light switch (not shown) for turning on the headlamp 60, a power switch 41 (see FIG. 8), and the like. The operation unit 40 also includes a mechanical manual switch 42 . Note that the installation location of the manual switch 42 can be changed as appropriate. Manual switch 42 accepts a push-walk operation for executing the second mode. The manual switch 42 is, for example, a momentary switch. Specifically, while the manual switch 42 is being pressed by the user, the operation unit 40 receives a signal for executing the second mode (second mode ON signal) emitted from the manual switch 42. , continues to output the second mode ON signal to the control device 22 (described later). That is, the operation unit 40 is an example of a reception unit that receives a signal for executing the second mode.

On the other hand, the operation unit 40 does not output the second mode ON signal to the control device 22 while the manual switch 42 is not pressed.

As shown in FIG. 1 , the saddle 15 is supported by a switching portion 152 . The saddle 15 is a part on which a person (user) sits when the user rides in an appropriate posture. The saddle 15 can be switched between a normal posture in which the seat surface of the saddle 15 is at a regular position and an irregular posture in which the seat surface of the saddle 15 is away from the regular position. Specifically, FIG. 1 illustrates a case where the saddle 15 is in a normal posture. FIG. 3 illustrates a case where the saddle 15 is in an irregular posture. When the saddle 15 is in the normal posture, this is an example of a first state in which the user can sit on the seat surface of the saddle 15 and drive. A case where the saddle 15 is in an irregular posture is an example of a second state different from the first state. In other words, the second state can also be said to be a state in which the user is seated on the seat surface of the saddle 15 during driving and cannot drive.

The switching portion 152 is a portion that switches the saddle 15 between the normal posture and the irregular posture. The switching unit 152 will be described in detail below with reference to FIGS. 4 to 7. FIG.

FIG. 4 is a perspective view showing the switching portion 152 in the normal posture according to the embodiment. FIG. 5 is a cross-sectional perspective view showing the switching portion 152 in the normal posture according to the embodiment. FIG. 6 is a perspective view showing the switching portion 152 in an irregular posture according to the embodiment. FIG. 7 is a cross-sectional perspective view showing the switching portion 152 in an irregular posture according to the embodiment.

As shown in FIGS. 4 to 7, the switching portion 152 includes a pedestal portion 153, a lever portion 154, an urging portion 155, and a state detection portion 156. As shown in FIGS.

The pedestal portion 153 is a portion that movably supports the saddle 15 . Specifically, the pedestal portion 153 includes a base portion 157 and a movable table 158 .

The base portion 157 is a metal member that integrally includes a body portion 1571 that rotatably holds the movable table 158 and a shaft portion 1572 that protrudes from the bottom of the body portion 1571 . A housing recess 1573 recessed downward is formed on the upper surface of the main body 1571 . The state detector 156 is accommodated and fixed in the accommodation recess 1573 . A through hole 1575 for rotatably supporting the movable table 158 is formed at the front end of the main body 1571 . In addition, a first strut 1579 erected upward is provided at the front end portion of the main body portion 1571 . One end of the biasing portion 155 is connected to the tip of the first support 1579 .

A projecting portion 1574 projecting rearward is provided at the rear end portion of the body portion 1571 . A slit 1578 for guiding the lever portion 154 is formed in the projecting portion 1574 along the front-rear direction. The lever portion 154 is rotatably supported on the main body portion 1571 while being arranged in the slit 1578 .

The movable table 158 is a part that supports the saddle 15 . The movable table 158 is rotatably held with respect to the body portion 1571 by inserting a shaft (not shown) through the through hole 1575 of the body portion 1571 . The movable table 158 is a metal cover body that partially covers the main body 1571 . A saddle 15 is fixed to the movable table 158 . That is, the saddle 15 moves following the motion of the movable base 158 .

A slit 1581 through which the first strut 1579 of the main body 1571 penetrates is formed in the front end of the movable table 158 . When the movable base 158 rotates after the regulation by the claw portion 1542 (described later) of the lever portion 154 is released, the first support 1579 moves relatively within the slit 1581, and finally the front end portion of the movable base 158 moves. The rotation of the movable table 158 is restricted by coming into contact with the front end portion of the main body portion 1571 . Hereinafter, the state in which the movable table 158 is restricted by the claw portion 1542 will be referred to as the closed state. In the closed state, the saddle 15 is in the normal posture. On the other hand, the state in which the front end portion of the movable base 158 is regulated by contacting the front end portion of the main body portion 1571 is referred to as an open state. In the closed state, the saddle 15 is in an irregular posture.

A second strut 1589 is provided at the rear end of the movable table 158 so as to stand upward. The other end of the biasing portion 155 is connected to the tip of the second support 1589 . The biasing portion 155 is, for example, a spring such as a coil spring. The biasing portion 155 applies a biasing force to the first support 1579 and the second support 1589 in a direction in which the first support 1579 and the second support 1589 approach each other. In this manner, the biasing portion 155 applies biasing force in the direction in which the movable table 158 is in the open state, that is, in the direction in which the saddle 15 is in the irregular posture.

The movable table 158 is provided with a shielding portion 1582 that overlaps the upper surface of the overhanging portion 1574 of the main body portion 1571 in the closed state to hide the overhanging portion 1574 . In the closed state, the distance between projecting portion 1574 and shielding portion 1582 is such that the user's finger cannot enter.

In addition, the movable table 158 has an arm portion 1583 extending into the housing recess 1573 of the main body portion 1571 . A magnet 1584 is fixed to the tip of the arm portion 1583 . Magnet 1584 is arranged close to state detector 156 . Since the magnet 1584 interlocks with the movement of the movable table 158 via the arm portion 1583, the relative positional relationship with the state detection portion 156 changes. For example, as shown in FIG. 5, the magnet 1584 is positioned near the lower end of the state detector 156 in the closed state. The position of the magnet 1584 in the closed state is defined as a reference position. On the other hand, as shown in FIG. 7, in the open state, the magnet 1584 is positioned above the reference position with respect to the state detection section 156 . The open position of the magnet 1584 is defined as the open position.

The lever portion 154 is, for example, a substantially L-shaped metal plate. A corner portion of the lever portion 154 is rotatably supported on the body portion 1571 . One end of the lever portion 154 is a grasping portion 1541 that is operated by the user. Grasping portion 1541 protrudes rearward from slit 1578 of main body portion 1571 . The other end portion of the lever portion 154 extends upward, and a claw portion 1542 is provided at the tip portion thereof. The claw portion 1542 is caught by the movable table 158 to restrict the rotation of the movable table 158 in the closed state. That is, the saddle 15 is maintained in the normal posture.

Further, when the grasping portion 1541 is operated by the user, the claw portion 1542 is separated from the movable table 158 by rotating the lever portion 154 . As a result, the restriction on the movable base 158 is released, so that the movable base 158 is rotated by the biasing force of the biasing portion 155 to be in the open state. That is, the saddle 15 assumes an irregular posture.

The state detection unit 156 is, for example, a magnetic proximity sensor, does not output a detection signal when the magnet 1584 is at the reference position, and outputs a detection signal when the magnet 1584 is at the open position. The magnet 1584 moves to the open position when the restriction by the lever portion 154 is released and the movable table 158 is opened. In other words, it can be said that the state detection section 156 detects that the regulation by the lever section 154 has been released. Thus, the state detection unit 156 is a sensor that detects the open state, that is, the irregular posture of the saddle 15 by detecting the position of the magnet 1584 .

The state detector 156 is housed inside the pedestal 153 so as to be covered with the pedestal 153 . Specifically, the state detection unit 156 is arranged in the housing recess 1573 of the base portion 157 that is part of the pedestal portion 153 and is covered with the movable table 158 that is part of the pedestal portion 153 . there is As shown in FIGS. 4 and 5, the state detector 156 is covered with the pedestal 153 even in the open state, the closed state, or transitional states thereof. In this manner, since the state detecting portion 156 is covered with the pedestal portion 153 made of metal as a whole, the state detecting portion 156 is prevented from being easily modified. From the viewpoint of preventing modification, the state detection section 156 may be completely covered by the pedestal section 153 , but a part of the state detection section 156 may be exposed from the pedestal section 153 . Specifically, a part of the state detecting portion 156 may be exposed through a slit provided in the base portion 153 or the like. In this case, the modification can be prevented by setting the slit to a size that makes it difficult for the tool to enter.

As shown in FIGS. 1 and 3 , the crank 16 has a crankshaft 161 and a pair of crank arms 162 . One crank arm 162 is provided on each side of the main frame 112 and fixed to both ends of a crank shaft 161 extending in the left-right direction. One end of the crank arm 162 is fixed to the crankshaft 161, and the pedal 17 is rotatably fixed to the other end. When a pedaling force is applied to the pedal 17 , the crank arm 162 rotates about the crankshaft 161 , and the human power driving force generated by this rotation is transmitted to the rear wheel 13 via the sprocket 18 and chain 19 . When operating in the first mode, the human-powered driving force based on the pedaling force and the first auxiliary driving force by the electric motor 21 added to the human-powered driving force are transmitted to the rear wheels 13 .

The motor drive unit 20 is unitized by housing an electric motor 21 and a control device 22 in a housing made of resin or metal.

The electric motor 21 is driven by receiving power from the battery 50 under the control of the control device 22 . Rotational torque of the electric motor 21 is transmitted to the sprocket of the rear wheel 13 to rotate the rear wheel 13 . Rotational torque means the first auxiliary driving force and the second auxiliary driving force. Further, the electric motor 21 can perform regenerative operation to generate regenerative electric power and charge the battery 50 during non-drive in which no motor output is produced, and can operate as a regenerative brake.

The electric motor 21 is a motor that serves as a first auxiliary driving force and a second auxiliary driving force. The electric motor 21 adds the first auxiliary driving force to the human-powered driving force based on the force applied to the pedal 17 while the first mode is being executed. In addition, the electric motor 21 adds the second auxiliary driving force to the power of pushing or supporting the electric bicycle 1 while the second mode is being executed.

FIG. 8 is a block diagram showing the configuration of the electric bicycle 1 according to the embodiment. As shown in FIG. 8, the control device 22 controls the operation of the electric motor 21 based on sensing information from sensors such as the crank rotation sensor 31, the pedaling force sensor 33, the current sensor 130, the vehicle speed sensor 243, and the gear stage measuring section 70. Control. In the present embodiment, the control device 22 is housed inside the housing of the motor drive unit 20, but it is not limited to this. The control device 22 may be provided separately from the motor drive unit 20 .

The control device 22 is realized by, for example, a microcomputer (microcontroller), etc., and includes a nonvolatile memory storing a program, a volatile memory that is a temporary storage area for executing the program, an input/output port, and executing the program. It consists of a processor that Alternatively, controller 22 may be implemented with dedicated electronic circuitry.

The control device 22 includes an electric motor 21, a crank rotation sensor 31, a pedal force sensor 33, a current sensor 130, a vehicle speed sensor 243, a gear stage measuring section 70, a power switch 41, an operating section 40, a battery 50, a state detecting section 156 and a front A light 60 is connected. An operation signal for each switch and a detection result by each sensor are input to the control device 22 .

The crank rotation sensor 31 and the pedaling force sensor 33 are arranged near the crankshaft 161 . The current sensor 130 is arranged near the rotating shaft of the electric motor 21 .

The crank rotation sensor 31 can detect the rotation speed of the crank 16 per unit time. The crank rotation sensor 31 is realized by having a gear-shaped rotating body and a photodetector having a light emitting portion and a light receiving portion arranged so as to sandwich the teeth of the rotating body. Note that the crank rotation sensor 31 may have any configuration as long as it can detect the rotation speed of the crank 16 .

The current sensor 130 is a circuit that calculates the value of current flowing through the electric motor 21 and outputs current information indicating the current value. Current sensor 130 has motor rotation sensor 32 and motor torque sensor 131 . The current sensor 130 calculates a current value using the number of revolutions per unit time of the electric motor 21 detected by the motor rotation sensor 32 and the torque of the electric motor 21 detected by the motor torque sensor 131 . The current value can be calculated by the motor rotation sensor 32 and the motor torque sensor 131 independently. Therefore, it is not always necessary to use both the motor rotation sensor 32 and the motor torque sensor 131 to calculate the current value.

The motor rotation sensor 32 has a magnet that rotates integrally with the rotating shaft of the electric motor 21 and a Hall IC. The Hall IC detects the number of rotations of the magnet per unit time, that is, the number of rotations of the electric motor 21, by detecting a change in the magnetic field that changes according to the rotation of the magnet. Note that the motor rotation sensor 32 may have any configuration as long as it can detect the rotation speed of the electric motor 21 .

A motor torque sensor 131 can detect the torque of the electric motor 21 . The motor torque sensor 131 is, for example, a magnetostrictive, strain gauge, or optical torque sensor, but is not limited thereto, and may be of any configuration as long as the torque of the electric motor 21 can be detected.

The pedaling force sensor 33 is a magnetostrictive torque sensor, and detects a human-powered driving force generated by rotating the crankshaft 161 based on the human-powered driving force applied to the pedals 17 . The pedal force sensor 33 has a coil and a magnetostriction generator. For example, when a pedaling force is applied to the pedal 17 to generate a human-powered driving force, distortion occurs in the magnetostrictive portion. The magnetostrictive portion has a portion where the magnetic permeability increases and a portion where the magnetic permeability decreases. By detecting the inductance difference between the coils, the human power driving force is detected. The configuration of the pedal force sensor 33 is not particularly limited, and any configuration may be used as long as it can detect the human power driving force applied to the pedal 17 . The manpower driving force is synonymous with the pedaling force.

The vehicle speed sensor 243 is provided at the lower end of the fork 114, for example. Vehicle speed sensor 243 detects the running speed of electric bicycle 1 from the rotation of front wheel 12 and transmits speed information indicating the running speed to control device 22 . The vehicle speed sensor 243 is, for example, a speed sensor or the like. The vehicle speed sensor 243 outputs speed information regarding the running speed of the electric bicycle 1 to the control device 22 . The speed sensor may be, for example, a wheel sensor or the like, but may also be a cycle computer that calculates ground speed, and may have any configuration as long as it can detect the speed of the electric bicycle 1 .

The gear stage measuring unit 70 measures the gear stage of the rear wheels 13 and transmits information indicating the gear stage to the control device 22 . The measurement of the gear stage may be realized by, for example, outputting to the control unit 221 information indicating the gear stage output by the gear stage switching device.

The control device 22 controls the operation of the electric motor 21, i.e., appropriate first assistance, based on sensing information from sensors such as the crank rotation sensor 31, the pedaling force sensor 33, the current sensor 130, the vehicle speed sensor 243, and the gear stage measuring unit 70. It controls the output of the electric motor 21 for applying the driving force and the second auxiliary driving force. In the present embodiment, the control device 22 is housed inside the housing of the motor drive unit 20, but it is not limited to this. The control device 22 may be provided separately from the motor drive unit 20 .

The control device 22 supplies power supplied from the battery 50 to the electric motor 21 and the headlight 60 .

The control device 22 has a control section 221 . The controller 221 drives the electric motor 21 according to the operation mode of the electric bicycle 1 . Specifically, the control unit 221 has a first mode and a second mode, and switches and executes the first mode and the second mode.

The assist mode, which is an example of the first mode, is a mode in which the vehicle travels by adding a first auxiliary driving force from the electric motor 21 to the human power driving force based on the force applied to the pedal 17 . The assist mode is executed when the user is riding the electric bicycle 1 after the power switch 41 is pressed to turn on the power. Specifically, the assist mode is executed when the force applied to the pedal 17 detected by the force sensor 33 is greater than a predetermined threshold.

The second mode is a mode in which the pushing force applied to the vehicle body 10 is added with a second auxiliary driving force by the electric motor 21 to push the vehicle, or a mode in which the vehicle is self-propelled by adding the second auxiliary driving force (push-walking mode or self-propelled mode). mode). In other words, the push-walking mode is a mode in which the electric motor 21 applies the second auxiliary driving force to the vehicle body 10 when the user pushes the electric bicycle 1 while the power is on. The push-walking mode is executed when the user is not riding the electric bicycle 1 and walks while pushing the body 10 of the electric bicycle 1 .

The self-running mode is a mode in which the electric bicycle 1 is self-running by applying the second auxiliary driving force from the electric motor 21 to the vehicle body 10 while the electric bicycle 1 is supported by the user. Similar to the push-walking mode, the self-propelled mode is executed when a person is not riding the electric bicycle 1 and walks while supporting the body 10 of the electric bicycle 1 . In the self-propelled mode, the user does not apply force to push the vehicle body 10 forward.

It should be noted that the push-walking mode and the self-propelled mode can be distinguished by the presence or absence of forward pushing force on the vehicle body 10 . For example, the control unit 221 may detect the presence or absence of a forward pushing force by a grip sensor or the like provided in the grip 141 or the like, and switch between the push-walking mode and the self-running mode according to the detection result. . Alternatively, the control unit 221 may execute the second mode in which the second auxiliary driving force is applied without distinguishing between the push-walking mode and the free-running mode.

When executing the assist mode, the control unit 221 determines the magnitude of the first auxiliary driving force generated by the electric motor 21 based on the force applied to the pedal 17 and the traveling speed of the electric bicycle 1 . The force applied to the pedal 17 is obtained from the detection result of the force sensor 33 . The running speed of the electric bicycle 1 is calculated by the vehicle speed sensor 243 .

A table in which the number of revolutions of the crank 16 and the speed of the electric bicycle 1 are associated in advance may be stored in the memory of the control device 22 . The control unit 221 may determine the traveling speed of the electric bicycle 1 from the rotation speed of the crank 16 by referring to the table.

The first auxiliary driving force in the assist mode varies depending on the traveling speed of the electric bicycle 1, but is, for example, twice or less than the force applied to the pedal 17. For example, when the traveling speed of the electric bicycle 1 is less than 10 km/h, the control unit 221 drives the electric motor 21 to generate a first auxiliary driving force that is less than twice the force applied to the pedal 17 . The control unit 221 does not cause the electric motor 21 to generate the first auxiliary driving force when the speed is 24 km/h or more. When the speed is 10 km/h or more and less than 24 km/h, the control unit 221 drives the electric motor 21 to generate the first auxiliary driving force determined according to the speed.

When the state detection unit 156 detects that the saddle 15 is in an irregular posture, the control unit 221 executes the second mode when the reception state is reached. The accepting state is a state in which the operating unit 40 accepts an operation (push-walking operation) for executing the second mode. Specifically, the acceptance state is a state in which a second mode ON signal is output from the operation unit 40 to the control device 22 by pressing the manual switch 42 by the user.

On the other hand, the control unit 221 prohibits execution of the second mode when the state detection unit 156 does not detect that the saddle 15 is in an irregular posture. The control unit 221 does not execute the second mode even if it enters the acceptance state during prohibition.

The control unit 221 stops the second mode when the accepting state is canceled during execution of the second mode. Cancellation of the accepting state is a state in which the operating unit 40 does not accept an operation for executing the second mode. Specifically, the user no longer presses the manual switch 42 and the second mode ON signal is not output from the operation unit 40 to the control device 22 .

Note that the second mode does not have to be executed when the force applied to the pedal 17 is greater than a predetermined threshold. That is, the first mode and the second mode are executed exclusively.

When executing the second mode, the control unit 221 causes the electric motor 21 to generate the second auxiliary driving force so that the running speed of the electric bicycle 1 does not exceed a predetermined upper limit. The second auxiliary driving force in the second mode is, for example, a magnitude that makes the speed of the electric bicycle 1 less than 6 km/h. Although the upper limit of the running speed of the electric bicycle 1 is 6 km/h here, it may be 3 km/h, and is not particularly limited.

The battery 50 is a storage battery that stores electric power for driving the electric motor 21 . The battery 50 is, for example, a secondary battery, but may be a capacitor or the like. Battery 50 is electrically connected to electric motor 21 . Specifically, the battery 50 supplies power to the electric motor 21 and charges regenerated power from the electric motor 21 .

[How to control an electric bicycle]
FIG. 9 is a flow chart showing the flow of the control method for the electric bicycle 1 according to the embodiment.

Here, assuming that the power switch 41 is turned on in advance, the process of causing the electric bicycle 1 to execute the second mode will be described. Note that if the power switch 41 is turned off during execution of the second mode, the power supply to the electric motor 21 is stopped, so the second mode is also stopped.

In step S1, the control unit 221 determines whether or not the state detection unit 156 has detected that the saddle 15 is in an irregular posture. If an irregular posture is detected, the process proceeds to step S3.

At step S2, the control unit 221 prohibits execution of the second mode. During the prohibition, the control unit 221 does not execute the second mode even if the acceptance state is entered.

In step S3, the control unit 221 determines whether or not the reception state is detected. If the reception state is detected, the process proceeds to step S3, and if the reception state is not detected, the process proceeds to step S1. Transition. If execution of the second mode is prohibited at the time of transition to step S3, the control unit 221 cancels the prohibition.

In step S4, the control section 221 executes the second mode. That is, when the second mode is executed, the saddle 15 is in the irregular posture, so the user is not seated on the saddle 15 .

In step S5, the control unit 221 determines whether or not the accepting state has been canceled. If the accepting state has been canceled, the process proceeds to step S6, and if the accepting state has not been canceled, the state continues.

In step S6, the control section 221 stops the second mode. After stopping the second mode, the control unit 221 terminates this process and returns to the beginning.

[Effect]
Next, the effects of the electric bicycle 1 and the control method of the electric bicycle 1 according to the present embodiment will be described.

As described above, the electric bicycle 1 according to the present embodiment includes the electric motor 21, and is an electric motor that can be switched between a first state in which the user can ride while seated and a second state that is different from the first state. The first mode in which the bicycle 1 runs by adding the first auxiliary driving force from the electric motor 21 to the human-powered driving force based on the force applied to the pedal 17, and the second auxiliary driving force from the electric motor 21 are applied to the vehicle body 10. A control unit 221 that switches and executes a second mode in which the robot is pushed by adding a pushing force to or self-propelled by adding a second auxiliary driving force, and an operation to receive a signal for executing the second mode. 40 (accepting unit), and a state detection unit 156 that detects that the electric bicycle 1 is in the second state. is detected, the second mode is executed when the operation unit 40 receives the signal, and the second mode is executed when the state detection unit 156 does not detect that the electric bicycle 1 is in the second state. prohibit the execution of

According to this, when the state detection unit 156 does not detect that the user is in the second state, execution of the second mode is prohibited. is prohibited. Therefore, it is possible to provide an electric bicycle that does not generate an auxiliary driving force for pushing while the user is riding the electric bicycle.

Since the state detection unit 156 only needs to detect the second state of the electric bicycle 1 , a sensor (for example, a magnetic proximity sensor) that is more stable than the pressure sensor can be used as the state detection unit 156 .

In addition, the electric bicycle 1 has a saddle 15 on which the user sits, and can be in a normal posture in which the seat surface of the saddle 15 is in a regular position and in an irregular posture in which the seat surface of the saddle 15 is away from the regular position. A switchable saddle 15 is provided, wherein the first state includes when the saddle is in the normal position and the second state includes when the saddle 15 is in the irregular position.

According to this, since the second state includes the case where the saddle 15 is in an irregular posture, execution of the second mode is prohibited due to the state of the saddle 15 in which the user is likely to actually sit. You can decide whether to

In addition, in order to maintain the normal posture of the saddle 15, the electric bicycle 1 has a lever portion 154 that regulates the movement of the saddle 15 and releases the regulation, and a lever portion 154 that is attached to the saddle 15 in an irregular posture. The state detection section 156 detects that the restriction by the lever section 154 has been released, thereby detecting the second state.

For example, it is conceivable that the user adjusts the posture of the saddle 15 using a tool or the like, but such posture adjustment is only for adjusting the posture during driving. Depending on the person, the saddle 15 may be adjusted to a posture that seems to be an irregular posture. If the state detection unit 156 erroneously determines that such a posture is an irregular posture, the second mode may not be prohibited even when the user is seated. Therefore, the state detection unit 156 detects the second state by detecting that the restriction by the lever unit 154 has been released, thereby preventing the above-described erroneous determination from occurring.

The electric bicycle 1 also includes a pedestal portion 153 that supports the saddle 15 and is interlocked with the movement of the saddle 15 . housed inside.

Here, it is conceivable that some people may execute the second mode even in the second state by remodeling the state detection unit 156 so that the second state cannot be detected. However, since the state detection section 156 is covered with the pedestal section 153, the state detection section 156 is prevented from being easily modified.

[Modification 1]
In the above-described embodiment, the case where the saddle 15 is in the irregular posture is exemplified as the second state. In this modified example 2, a case where the state in which the pedal 17a is folded is also included in the second state is illustrated. In the following description, parts that are the same as those in the above-described embodiment are denoted by the same reference numerals, and description thereof may be omitted.

FIG. 10 is a side view showing an electric bicycle 1A according to Modification 1. FIG. FIG. 10 shows a state in which the pedal 17a is folded. Specifically, the pedal 17a is provided foldably with respect to the crank arm 162 . The state in which the pedals 17a are not folded is the same as that of the electric bicycle 1 shown in FIG. When the pedals 17a are folded, the user cannot step on the pedals 17a even when seated on the saddle 15 . In other words, the vehicle cannot be driven. Therefore, the state in which the pedal 17a is folded can be included in the second state. On the other hand, the state in which the pedal 17a is not folded can be included in the first state.

A second state detector (not shown) is also provided for the pedal 17a. The second state detection unit detects that the pedal 17a is in the second state by detecting the state in which the pedal 17a is folded.

The second state detector is communicatively connected to the controller 221 . Although it is possible to electrically connect the second state detection unit and the control unit 221 by wiring, since the wiring is through the crank arm 162, the deterioration progresses due to the rotation of the crank arm 162. may be hastened. In order to prevent such deterioration, the second state detection section may be connected to the control section 221 wirelessly so as to be communicable.

The control unit 221 switches to the second mode when at least one of the state detection unit 156 detects that the saddle 15 is in an irregular posture and the second state detection unit detects that the pedals 17a are folded. prohibit the execution of

In this way, when a plurality of state detection units (the state detection unit 156 and the second state detection unit) are provided, the detection results of these state detection units are used in a composite manner so that the control unit 221 operates in the second mode. Therefore, even when the user is riding the electric bicycle, it is possible to more reliably prevent the generation of the auxiliary driving force for pushing while walking.

It should be noted that in Modification 1, the electric bicycle 1A provided with the state detection section 156 and the second state detection section is exemplified. However, the electric bicycle may include only the second state detection section.

[Modification 2]
In the above-described embodiment, the case where the manual switch 42 of the operation unit 40 that receives the operation for executing the second mode is provided on the handle 14 has been exemplified. In this modified example 2, a case where the manual switch of the operating section is provided in the switching section of the saddle is illustrated. In the following description, parts that are the same as those in the above-described embodiment are denoted by the same reference numerals, and description thereof may be omitted.

FIG. 11 is a perspective view showing a switching portion 152b in an irregular posture according to Modification 2. As shown in FIG. As shown in FIG. 11, the manual switch 42b is arranged on the upper surface of the projecting portion 1574b of the base portion 157b of the switching portion 152b. Thereby, the manual switch 42b is arranged in the vicinity of the grasping portion 1541 of the lever portion 154. As shown in FIG. As described above, the upper surface of the projecting portion 1574b is hidden by the shielding portion 1582 of the movable table 158 in the normal posture (see FIGS. 4 and 5). In addition, the upper surface of the overhanging portion 1574 is in an exposed state in the irregular posture (see FIG. 11). In this manner, the manual switch 42b is hidden in the normal posture, and is arranged at a location (upper surface of the projecting portion 1574) exposed in the irregular posture. In other words, the manual switch 42b is also hidden by the shielding portion 1582 in the normal posture. Since the manual switch 42b is hidden in this manner, the user cannot operate the manual switch 42b in the normal posture, and as a result, the second mode cannot be executed. On the other hand, since the manual switch 42b is exposed in the irregular posture, the user can operate the manual switch 42b. The user must necessarily be off the saddle 15 to operate the exposed manual switch 42b. That is, since the user cannot operate the manual switch 42b during driving, it is possible to reliably prevent execution of the second mode during driving.

The electric bicycle 1 also includes a movable stand 158 that supports the saddle 15, and a base portion 157 that holds the movable stand 158 so that the movable stand 158 is rotatably held so that the normal posture and the irregular posture are switched. , and the manual switch 42 b is provided on the base portion 157 .

According to this, since the manual switch 42b is provided on the base portion 157 that does not rotate, it is possible to have a simple structure.

In addition, in order to maintain the normal posture of the saddle 15, a lever portion 154 that regulates the movement of the saddle 15 and releases the regulation, and an attachment that imparts a biasing force to the saddle 15 in the direction of the irregular posture. The manual switch 42b is arranged in the vicinity of the grasping portion 1541 of the lever portion 154. As shown in FIG.

According to this, since the manual switch 42b is arranged in the vicinity of the grasping portion 1541 in the lever portion 154, it is possible to smoothly shift from the release operation to the grasping portion 1541 to the operation to the manual switch 42b.

If the manual switch 42b of the operation unit 40 is arranged in a position that is hidden when the saddle 15 is in the normal posture and is exposed when the saddle 15 is in the irregular posture, the state detection unit Even without 156, it is possible to prevent execution of the second mode while driving. That is, the electric bicycle 1 includes the electric motor 21, and the first mode in which the first auxiliary driving force by the electric motor 21 is added to the human power driving force based on the pedaling force on the pedal, and the second mode by the electric motor 21. A control unit 221 for switching and executing a second mode in which the second auxiliary driving force is added to the pushing force to the vehicle body to push, or the second auxiliary driving force is added to self-run, and the second mode is executed. a manual switch 42b (operation unit) that accepts an operation for the purpose, a normal posture in which the seat surface of the saddle 15 on which the user sits is in a normal position, and a normal posture in which the seat surface of the saddle 15 is in a normal position. and a saddle 15 that can be switched between a remote posture and an irregular posture, and the control unit 221 executes the second mode when the manual switch 42b receives the operation, and the manual switch 42b sets the saddle 15 in the regular posture. In some cases, the saddle 15 may be hidden, and when the saddle 15 is in an irregular posture, the saddle 15 may be arranged in an exposed position.

[others]
As described above, the electric bicycle according to the present invention has been described based on the above embodiment, but the present invention is not limited to the above embodiment.

For example, in the above-described embodiment, the saddle 15 rotates around a shaft parallel to the left-right direction, thereby switching between the normal posture and the irregular posture. However, the direction of rotation of the saddle 15 is arbitrary. For example, the normal posture and the irregular posture may be switched by rotating the saddle 15 around a shaft parallel to the front-rear direction.

In the above-described embodiment, the state detection unit 156 does not output a detection signal when the magnet 1584 is at the reference position, and outputs a detection signal when the magnet 1584 is at the open position. 15 is assumed to be in an irregular posture. However, even if the output condition of the detection signal is reversed, it is possible for the state detection unit 156 to detect that the saddle 15 is in an irregular posture. In other words, even a sensor that detects the normal posture of the saddle 15 can be said to detect an irregular posture if it does not detect the normal posture. .

Further, in the above embodiment, the state detection unit 156 detects that the saddle 15 is in the irregular posture when the magnet 1584 is in the open position. However, an angle sensor that detects the angle of the seat surface of the saddle 15 can be used as the state detection unit. In this case, if the detected angle of the seat surface is 45 degrees or more, preferably 60 degrees or more with respect to the horizontal plane, the state detection section may determine that the saddle 15 is in an irregular posture. Also, the threshold for determining that the saddle 15 is in an irregular posture can be set in the range of 30 degrees to 270 degrees. In this case, it is preferable that the angle can be set stepwise in increments of 10 degrees within the range of 30 degrees to 90 degrees. Further, the state detection unit may determine that the saddle 15 is in the irregular posture when it detects that the seat surface of the saddle 15 is tilted from the normal posture.

The angle sensor may directly detect the angle of the seat surface with respect to the horizontal plane, or may indirectly detect the angle of the seat surface by detecting the rotation angle of the movable table 158 .

In the above-described embodiment and modified example 1, the first state in which the user can sit and ride the electric bicycle 1 is the normal posture of the saddle 15 and the state in which the pedals 17 are not folded. By the way, even if the saddle 15 is in an irregular posture, it is possible for the user to sit on the seat surface of the saddle 15 in an unreasonable posture and drive. In other words, the first state can also be interpreted as including a state in which the user can sit and drive if the user is in an unreasonable posture. However, such a position impairs driving stability and is generally not recommended by the manufacturer. Therefore, the first state can also be defined as a state in which the user can sit and drive in a posture recommended by the manufacturer.

Further, in the case of an electric bicycle having a carrier on the rear wheel, it is assumed that the user may sit on the carrier while driving. Also in this case, the second mode may be prohibited. Specifically, the loading platform can be switched between a loadable state in which a load can be placed on the loading platform (a state in which a user can sit on the loading platform) and an unloadable state in which a load cannot be placed on the loading platform. and Also, the electric bicycle may be provided with a sensor that detects the second state by detecting the unmountable state as the state detection unit. When the sensor detects the second state, the control unit prohibits execution of the second mode. Therefore, even if the user sits on the loading platform and drives, execution of the second mode is prohibited.

Further, in the case of an electric bicycle equipped with a folding handle, the state in which the handle is folded can be the second state. In this case, the electric bicycle may be provided with a sensor that detects the state in which the handlebars are folded as a state detection unit.

As the second state of the electric bicycle, any state can be applied as long as it is different from the first state in which the user can sit and ride the electric bicycle.

Further, in the above embodiment, the magnetic proximity sensor is exemplified as the state detection unit 156 . However, any sensor can be employed as the state detection section as long as it can detect the second state of the electric bicycle. Other sensors include electrical sensors, optical sensors, image sensors, and the like.

Further, in the above embodiment, the operation unit 40 is exemplified as an example of the reception unit. However, any reception unit may be used as long as it receives a signal for executing the second mode. For example, if the electric bicycle is provided with a pressure sensor that detects the pressure applied by the user, the signal output by the pressure sensor that detects the pressure is used as the signal for executing the second mode. It is also possible to In this case, the control section that receives the signal from the pressure sensor becomes the reception section.

Further, in the above embodiments, all or part of the components of the control device may be configured with dedicated hardware, or may be realized by executing a software program suitable for each component. good. Each component may be implemented by a program execution unit such as a CPU (Central Processing Unit) or processor reading and executing a software program recorded in a recording medium such as a HDD (Hard Disk Drive) or semiconductor memory. good.

Also, the components of the controller 22 may consist of one or more electronic circuits. Each of the one or more electronic circuits may be a general-purpose circuit or a dedicated circuit.

One or more electronic circuits may include, for example, a semiconductor device, an IC (Integrated Circuit), or an LSI (Large Scale Integration). An IC or LSI may be integrated on one chip or may be integrated on a plurality of chips. Although they are called ICs or LSIs here, they may be called system LSIs, VLSIs (Very Large Scale Integration), or ULSIs (Ultra Large Scale Integration) depending on the degree of integration. An FPGA (Field Programmable Gate Array) that is programmed after the LSI is manufactured can also be used for the same purpose.

Also, general or specific aspects of the invention may be implemented in a system, apparatus, method, integrated circuit or computer program product. Alternatively, the computer program may be implemented by a computer-readable non-temporary recording medium such as an optical disc, HDD, or semiconductor memory. Also, any combination of systems, devices, methods, integrated circuits, computer programs and recording media may be implemented.

In addition, it can be realized by applying various modifications to each embodiment that a person skilled in the art can think of, or by arbitrarily combining the constituent elements and functions of each embodiment without departing from the spirit of the present invention. Forms are also included in the present invention.

1, 1A electric bicycle 15 saddle 21 electric motor 42b manual switch (operation unit)
153 pedestal portion 154 lever portion 155 biasing portions 157, 157b base portion 158 movable table 221 control portion 1541 grasping portion

Claims (3)

An electric bicycle comprising an electric motor,
A first mode in which the vehicle travels by adding a first auxiliary driving force by the electric motor to the human power driving force based on the force applied to the pedal, and a second mode in which the second auxiliary driving force by the electric motor is added to the pushing force on the vehicle body. a control unit that switches between and executes a second mode in which the robot is pushed while walking or self-propelled by applying the second auxiliary driving force;
an operation unit that receives an operation for executing the second mode;
A saddle on which a user sits, comprising a saddle that can be switched between a normal posture in which the seat surface of the saddle is in a regular position and an irregular posture in which the seat surface of the saddle is away from the regular position,
The control unit executes the second mode when the operation unit receives the operation,
The electric bicycle, wherein the operation unit is hidden when the saddle is in the normal posture and is exposed when the saddle is in the irregular posture. a movable base that supports the saddle;
a base unit that holds the movable table such that the movable table is rotatably held so that the normal posture and the irregular posture are switched;
The electric bicycle according to claim 1, wherein the operation portion is provided with respect to the base portion. a lever portion that regulates the movement of the saddle and releases the regulation in order to maintain the normal posture of the saddle;
a biasing unit that applies a biasing force to the saddle in a direction of the irregular posture;
The electric bicycle according to claim 2, wherein the operating portion is arranged in the vicinity of the grasping portion of the lever portion.

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