JP3710906B2 - Vehicle with auxiliary power - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a vehicle with auxiliary power that has both a human-powered drive unit by human power and an electric drive unit driven by a motor or the like and that can travel using two forces in combination.
[0002]
[Prior art]
Conventionally, this type of vehicle with auxiliary power is a human-powered drive unit using a pedal driving force and an electric motor driven by a motor, such as an assist type electric bicycle disclosed in Japanese Patent Application Laid-Open No. 8-11772 (B62M23 / 02). It is known that a driving unit is provided, and the human driving force can be suppressed to half that of a normal bicycle by applying an electric driving force having the same magnitude as that of the human driving unit.
[0003]
Further, as a vehicle with auxiliary power of this type, an electric drive unit and a human drive unit are provided in the bicycle body as in a motorcycle type electric bicycle shown in JP-A-6-156360 (B62M23 / 02). Is driven by operating an accelerator provided in the vicinity of the steering wheel, and the human-powered driving unit is known to operate independently of the electric driving unit.
[0004]
In the above-mentioned two types of assist-type and motorcycle-type vehicles with auxiliary power, the bicycle body is provided with a one-foot stand to support the body when the vehicle is stopped. It is known that the vehicle is lifted when starting to run so as not to interfere with the running.
[0005]
However, in the case of a bicycle as described above, the stand is usually raised at the start of running, but if you forget to start running, when the bicycle body tilts due to a curve, etc., a wall beside the running road, etc. When there is an obstacle, the stand is lowered, so that the stand hits a road surface or an obstacle, resulting in a very dangerous problem.
[0006]
In addition, when the stand is lowered and the vehicle is stopped, an operation that operates the electric drive unit, for example, when the motorcycle is operated, the accelerator is operated, and when the assist type is operated, the pedal is depressed. In spite of standing up by the stand, there is a problem that it is very dangerous because it pops forward by the operation of the electric drive unit regardless of the intention of the user.
[0007]
In addition, when the stand is a two-foot stand, the wheel floats from the ground when the stand is standing, so that the wheel can be rotated by driving the electric drive unit by operating the accelerator or inputting a human torque signal. I can do it.
[0008]
In this way, when the wheel is floating and rotating while stopping, if the stand rises and the rotating wheel is installed on the ground, there is a high possibility of sudden start, and a person is on Had the problem of being very dangerous. Even if the stand stands and the wheels are floating from the ground, if the wheels rotate while the vehicle is stopped, the surrounding people may be touched, which is very dangerous.
[0009]
[Problems to be solved by the invention]
The present invention has been made in view of the above-described drawbacks, and an object thereof is to provide a vehicle with auxiliary power that has improved safety during traveling and stopping.
[0010]
[Means for Solving the Problems]
  The present invention provides a vehicle main body provided with an electric drive unit using a motor as a drive source and a human drive unit using human power as a drive source;An accelerator for manipulating the magnitude of the output of the electric drive unit; andA stand that can be raised and lowered to support the standing of the main body while the vehicle main body is stopped, and is provided with an elevating detection unit that detects the elevating state of the stand, and when the stand is lowered, the electric drive unit is operated. Provide a control circuit to stopWhen the accelerator is operated and the stand is lifted from the lowered position, the control circuit gradually increases the signal output to the electric drive unit from a small value to a command value of the accelerator over time. It has a soft start sectionIt is characterized by that.
[0011]
  Further, the present invention provides a vehicle body provided with an electric drive unit using a motor as a drive source, a human drive unit using human power as a drive source, a torque detection unit for detecting the drive force of the human drive unit, An elevating / lowering stand for supporting the standing of the main body while the vehicle main body is stopped, and an elevating detector for detecting the elevating state of the stand. When the stand is lowered, the operation of the electric drive unit When the stand is raised, a control circuit for controlling the electric drive unit based on the signal of the torque detection unit is provided, and the control circuit is in a state where the driving force is applied to the human power drive unit. And a soft start portion that gradually brings a signal output to the electric drive portion from a small value to a human drive force as time elapses when the stand is raised from the lowered position.
[0013]
With the above configuration, when the vehicle main body including the electric drive unit and the human drive unit is stopped with the stand lowered, the electric drive unit does not operate even if there is an operation for operating the electric drive unit. In addition, even if the driving is started by the human driving force with the stand lowered, the driving force by the electric driving force is not output.
[0014]
Then, an accelerator is provided as means for operating the electric drive unit, and even if the stand is raised from the lowered position while the accelerator is operated, the electric drive force is not suddenly output and is small by the soft start unit. The value gradually increases from the value to the value indicated by the accelerator.
[0015]
In addition, the electric drive unit is operated by the control circuit based on the signal of the torque detection unit, and even if the stand is raised from the lowered position in a state where there is human power drive force, the electric drive force is suddenly applied. Rather, the soft start part gradually increases from a small value so as to approach the human driving force.
[0016]
DETAILED DESCRIPTION OF THE INVENTION
An embodiment of the present invention will be described in detail below with reference to FIGS. 1 to 6, taking an electric bicycle as an example.
[0017]
First, the overall configuration of the electric bicycle will be described with reference to FIG.
[0018]
Reference numeral 1 denotes a vehicle main body based on a main frame connected to a head pipe 2 provided at a front portion and a seat tube 4 provided below from a saddle 3, and the main body 1 is manually attached to a lower end of the seat tube 4. The pedal 5 which can be rotated by is attached.
[0019]
Reference numeral 6 denotes a front wheel that moves in conjunction with the movement of the handle 7 and moves to the left and right by the operation of the handle 7.
[0020]
  11 is a rear wheel serving as a drive wheel, and the rear wheel 11 is also composed of a tire 12, a rim 13, a spoke 14, and an electric drive unit for driving the rear wheel 11, that is, a drive unit 15. .
[0021]
  Reference numeral 16 denotes a front sprocket that rotates with the rotation of the pedal 5, and a chain 17 is applied to the front sprocket 16 so that the rotation of the front sprocket 16 is transmitted to the rear sprocket provided on the axle of the drive unit 15. It has become.
[0022]
  Reference numeral 18 denotes a battery serving as a power source for the motor 36. The battery 18 includes 20 1.2-volt cell batteries connected in series and built in a case. Further, the battery 18 is removable and can be charged indoors when charging.
[0023]
Reference numeral 19 denotes a stand that is rotatable with respect to the main body 1 in two directions, a horizontal state and a vertical state. The stand 19 is lowered so that the main body 1 does not fall while the main body 1 is stopped. 1 is provided to support 1 and prevent it from falling over. Also, when traveling, it is raised horizontally to the main body 1 so as not to get in the way.
[0024]
Next, the stand 19 will be described with reference to FIG.
[0025]
Reference numeral 20 denotes an attachment plate provided in the vicinity of the drive unit 15 of the main body 1, and the attachment plate 20 is provided with the stand 19 so as to be rotatable. Further, the attachment plate 20 has a claw 21 formed below.
[0026]
Reference numeral 22 denotes a lock plate rotatably provided on the stand 19, and the lock plate 22 engages with the claw 21 by rotating when the stand 19 is lowered, so that the stand 19 rotates. That is, the stand 19 is prevented from rising.
[0027]
23 is a spring having one end attached to a part of the lock plate 22 and the other end attached to a part of the mounting plate 20. The spring 23 is always pulled so that the lock plate 22 is above the stand 19. Thus, the claw 21 and the lock plate 22 are prevented from naturally engaging when the stand 19 is lowered. That is, the claw 21 and the lock plate 22 are not engaged unless the lock plate 22 is rotated by the user's intention.
[0028]
Reference numeral 24 denotes an elevation detection unit, that is, a micro switch attached to the back side of the mounting plate 20. The micro switch 24 is turned on when the stand 19 is lowered and turned off when the stand 19 is raised. Abuts or leaves part of 19
[0029]
Next, the accelerator 25 that is provided on the right grip of the handle 7 and adjusts the output of the drive unit 15 will be described with reference to FIG.
[0030]
Reference numeral 26 denotes a rotating cylinder that is rotatably fitted to the right end of the handle 7. The rotating cylinder 26 is configured to increase the traveling speed by the user rotating with the right hand.
[0031]
27 is a ring-shaped spring having one end engaged with a part of the rotating cylinder 26 and the other end engaged with a part of an accelerator cover 32 described later. The spring 27 is rotated by the user. It is energized to return to its original state when not being moved.
[0032]
An arc-shaped magnet 28 is provided on the rotating cylinder 26, and the magnet 28 rotates with the rotation of the rotating cylinder 26.
[0033]
Reference numeral 29 denotes a substrate on which a plurality of reed switches 30 are provided so as to face the moving range of the magnet 28, and the substrate 29 sends an accelerator signal to the driving unit 15 via a lead wire 31.
[0034]
An accelerator cover 32 covers a part of the rotating cylinder 26, the magnet 28, the substrate 29, and the spring 27 from above and below, and is fixed to the handle 7 by the accelerator cover 32.
[0035]
With this configuration, when the rotating cylinder 26 is rotated by the user, the magnet 28 moves. At this time, the plurality of reed switches 30 provided to face the moving range of the magnet 28 start operation one by one by the magnet 28. For example, only one reed switch 30 is operated if it is rotated a little, and four reed switches 30 are operated when it is rotated to the maximum. Can be entered.
[0036]
Next, the control circuit will be described with reference to FIG.
[0037]
Reference numeral 33 denotes an accelerator circuit that outputs an accelerator signal including the reed switch 30 and the substrate 29. The accelerator circuit 33 inputs an input signal to the control circuit 34.
[0038]
  35 is a motor drive circuit that inputs a signal from the control circuit 34 based on a signal from the accelerator circuit 33. The motor drive circuit 35 is configured to drive a motor 36 provided in the drive unit 15 by a drive switching element 37. PWM control is performed. Further, the control circuit 34 is provided with a soft start unit that gradually approaches the instruction signal from the accelerator circuit 33 as time elapses, and the soft start unit operates based on a flowchart described later.
[0039]
  Reference numeral 38 denotes a constant voltage circuit that steps down the voltage of 24 volts to 5 volts and serves as a power source for the control circuit 34.
[0040]
  39 is a flywheel diode connected to the motor 36 in parallel.
[0041]
  A power switch 40 intervenes in a circuit connecting the motor 36 and the battery 18, and the power switch 40 is operated by a user to turn on the power to the drive unit 15.
[0042]
41 is a shunt resistor connected to the switching element 37.
[0043]
A voltage detection circuit 42 divides the voltage of the battery 18 and outputs the divided voltage to the control circuit 34. Reference numeral 43 denotes a current detection circuit that is connected between the switching element 37 and the shunt resistor 41, amplifies this signal, and outputs the amplified signal to the control circuit.
[0044]
44 is a battery remaining amount display circuit for displaying the remaining amount of the battery 18 based on the signals from the voltage detection circuit 42 and the current detection circuit 43, and the battery remaining amount display circuit 44 is composed of a plurality of LEDs and the like. The remaining amount is indicated by the number of lit LEDs.
[0045]
Next, the operation in the above-described configuration will be described with reference to FIGS.
[0046]
The flowchart in FIG. 5 shows only the setting of the output value of the electric driving force.
[0047]
When the bicycle descends from the stand 19 and stops, the state where the bicycle is descending is input to the control circuit 34 (S1). When the stand 19 continues in the lowered state, the electric driving force K is zero, that is, the operation by the electric driving force is not performed (S2). When the stand 19 is raised, the instruction value A of the accelerator 25 is input (S3), and it is determined whether the input signal from the accelerator circuit 33 and the output signal to the drive unit 15 are the same (S4). . If they are the same, it is determined that the accelerator 25 is not operated, and it is determined again whether the stand 19 is raised (S1). If the input signal from the accelerator circuit 33 and the output signal to the drive unit 15 are different, the process proceeds to the next. Next, when the input signal from the accelerator circuit 33 and the output signal to the drive unit 15 are different, for example, when the input signal from the accelerator circuit 33 is larger, the accelerator 25 is operated in the direction of increasing the speed. Judgment is made, and the output signal to the drive unit 15 is gradually increased one by one (S6). After incrementing by 1, when returning to the beginning of this routine and passing through this portion again, 1 is added to the output signal 1 at the time of first passing to become 2. If this state continues, the speed will gradually increase with time. A so-called soft start is performed.
[0048]
Next, after the start of traveling, the signal from the accelerator circuit 33 and the signal to the drive unit 15 are compared (S5), and when the accelerator 25 is returned to the lower speed, the input from the accelerator circuit 33 and the drive unit Control is performed so that the output to 15 is the same (S7).
[0049]
In addition, it is determined whether or not the stand 19 is always raised during traveling (S1). If the stand 19 is lowered during traveling, there is a risk that the stand 19 and the ground may come into contact with each other. The electric driving force K is set to zero (S2), and the electric driving force is stopped.
[0050]
As shown in FIG. 6, the above-described flowchart is shown in the signal input / output state and timing chart.
[0051]
This timing chart shows the signal from the micro switch 24 above, and the state where the signal is present indicates the state where the stand 19 is lowered, that is, the state where the micro switch 24 is turned on. The input state of the next signal is a timing chart showing the accelerator signal from the accelerator 25. There are as many signals as there are reed switches 30, and the accelerator signal is output in four stages. Then, the user indicates a greater driving force as the waveform height increases. The timing chart shown at the bottom is a signal for operating the electric driving force, and a signal corresponding to the magnitude of the accelerator signal is output.
[0052]
First, the position of the stand 19 is raised, and when an accelerator signal is input from the accelerator circuit 33, the electric drive signal gradually rises accordingly (A). At this time, the rise of the output signal to the drive unit 15 is slanted because there is a portion of S6 in the flowchart described above, and the drive signal gradually increases. When the accelerator signal becomes small, for example, when the running is finished, the electric drive signal becomes small and the driving is finished (B). When the stand 19 is lowered, a signal indicating that the stand 19 is lowered is input (C).
[0053]
At this time, when the accelerator 25 is operated, an accelerator signal is input from the accelerator circuit 33 (D). When the stand 19 is raised in this state (E), the electric drive signal gradually rises to the value of the accelerator signal. I will start slowly. Then, with the passage of time, it becomes the same value as the accelerator signal (F). Then, when the stand 19 is lowered during traveling, the electric drive signal stops despite the presence of the accelerator signal, and the traveling by the electric driving force is stopped (G).
[0054]
As described above, since the control circuit 34 for stopping the operation of the drive unit 19 is provided when the stand 19 is lowered, the accelerator 25 can be operated when the stand 19 is lowered and stopped. Since the drive unit 15 does not operate, it does not start suddenly against the user's intention and is very safe. Also, when the stand 19 is lifted from the lowered position, the signal output to the drive unit 15 gradually approaches the indicated value of the accelerator 25 from a small value as time passes, so the stand 19 is raised with the accelerator 25 operated. However, it does not start suddenly and is safe. Further, when the vehicle is traveling with the stand 19 lowered, there is no output from the drive unit 15 even if the accelerator 25 is operated, and only the human driving force is used to travel. You will notice that it is down and you can prevent danger.
[0055]
Next, the second embodiment will be described. In this embodiment, an electric bicycle including an electric drive unit and a human power drive unit and outputting an electric drive force having the same magnitude as the human power of the human power drive unit will be described. In this embodiment, since the electric drive unit outputs an electric drive force based on human power, the accelerator 25 used in the first embodiment is not provided.
[0056]
First, a block diagram of the control circuit will be described with reference to FIG. In the present embodiment, the same parts as those in the first embodiment are denoted by the same reference numerals and description thereof is omitted.
[0057]
A torque detection unit 45 detects the magnitude of the human driving force applied to the pedal 5, and a signal input from the torque detection unit 45 is input to the control circuit 34. Based on this signal, a driving signal is output to the motor driving circuit 35 so as to have the same driving force as human power, the switching element 37 is turned on and off, and the motor 36 is driven.
[0058]
Next, a specific configuration of the drive unit 15 is shown in FIGS.
[0059]
  Reference numeral 46 denotes a disk-shaped fixed casing that is fixedly attached to the main frame 1, and 47 is a rotating casing that rotates coaxially with the fixed casing 46 and rotates outside the fixed casing 46. The fixed casing 47 and the rotating casing 46 are combined to form a hub of the rear wheel 11. The stationary casing 47 and the rotating casing 46 are made of an aluminum alloy having a thickness of about 2 mm.
[0060]
  Reference numeral 48 denotes an L-shaped annular rib provided on the outer periphery of the rotation-side casing 46. The annular rib 48 is fixed to the rotation-side casing 46 at a plurality of locations, and the tire 12 is attached to the annular rib 48. A spoke 14 is stretched toward the rim 13 that is attached.
[0061]
  Reference numeral 36 denotes a motor serving as a drive source, 49 is a rotor, and 50 is a stator. The motor 36 is mounted on the stationary casing 47, and a portion of the motor 36 protruding from the rotating casing 46 is covered with a motor cover 51, and the output shaft 52 of the motor 36 is supported by a bearing 53. ing.
[0062]
  Reference numeral 54 denotes a planetary roller speed reduction mechanism screwed to the fixed casing 47 and fitted to the holding portion 55. The planetary roller speed reduction mechanism 54 is disposed around the same axis as the output shaft 52.
[0063]
  A first pulley 56 is mounted on the output shaft 52 through two bearings and coaxially with the output shaft 52 through a one-way clutch 57. A rubber belt 58 is hung on the first pulley 56. It has been.
[0064]
  Reference numeral 59 denotes a second pulley on which the other end of the belt 58 is hung. The second pulley 59 is fixed to the rotating side casing 46 by a bolt 60. The second pulley 59 has a hollow inside, and a torque detector 45 is provided therein.
[0065]
  61 is a tension pulley for adjusting the tension of the belt 58. The tension pulley 61 has a roller 63 attached to one end of a support 62, and a screw 64 for attaching to the stationary casing 47 at the other end. The support body 62 can swing around the part where the screw 64 is attached, the tension pulley 61 is fixed by tightening the other screw 65, the belt 58 is pressed, and the tension of the belt 58 is increased. Can be adjusted.
[0066]
  66 is a control board built in the fixed casing 47, and the control board 66 is built in a portion without a pulley. In addition to the microcomputer that controls the rotation of the motor 36 according to the output result from the torque detection unit 45, the control board 66 is a drive circuit that performs PWM control of the motor 36 and a constant voltage circuit for inputting a starting voltage to the microcomputer, Equipped with a torque detection circuit.
[0067]
  67 is a rear sprocket on which the chain 17 is hung. The rear sprocket 67 is provided to the axle 68 via a bearing 69 and is attached to a rotating plate 74 described later via a one-way clutch 70. ing.
[0068]
  Reference numeral 71 denotes a rotating cylinder provided on the axle 68 via a bearing 72. The rotating cylinder 71 rotates with the rotation of the rotary casing 46.
[0069]
  Reference numeral 45 denotes a torque detection unit attached in the vicinity of the second pulley 59 and the axle 68. The torque detection unit 45 is provided for detecting a human driving force transmitted through the chain 17, that is, a human torque. ing.
[0070]
The torque detector 45 will be described.
[0071]
The rotating plate 74 is concentric with the axle 68, and a pressing rod 75 and a conversion rod 76 are integrally formed in two opposite positions in the axial direction. The pressing rod 75 is formed in a pillar shape with a bell-shaped surface, and an elastic body, that is, a spring 77 is pressed by a curved surface portion of the bell-shaped. The rotating plate 74 expands and contracts the spring 77, and the second pulley 59 rotates while the other end of the spring 77 presses the inner wall of the second pulley 59. The conversion rod 76 is a rectangular parallelepiped extending in the direction of the axle 68, and is formed obliquely so that the tip portion becomes shorter in the rotation direction.
[0072]
The other end of the spring 77 pressed by the pressing rod 75 is in contact with a part of the rotating side casing 46, and the pressing rod 75 and the spring 77 are expanded and contracted from the rotating plate 74 as an order of transmission of the human driving force. The rotation side casing 46 is rotated. At this time, the rotating plate 74 rotates while causing a slight distortion with the rotating casing 46 according to the expansion / contraction size of the expanded / contracted spring 77. The rotating plate 74 rotates according to distortion caused by human power. At this time, the conversion rod 76 is also rotated by a slight rotation of the rotation plate 74, and the angled portion 78 in contact with the inclined portion is pushed by the inclined portion formed at the tip of the conversion rod 76 to move in the direction of the axle 68. An aluminum ring 79 is attached to the angle portion 78, and the ring 79 is also moved by the movement of the angle portion 78. A C-ring 80 and a spring 81 for urging the ring 79 toward the rotating plate 74 are provided at the tip of the ring 79. Therefore, the ring 79 moves in the direction of the axle 68 by the amount of distortion of the rotating casing 46 and the rotating plate 74.
[0073]
  82 is a coil provided in the vicinity of the ring 79 in the fixed casing 46. The coil 82 can convert an inductance change due to the approach of the ring 79 into an electrical signal, and uses this output. Thus, it is possible to detect human torque. These members are collectively referred to as the torque detection unit 45. Here, the conversion rod 76, the chevron part 78, the ring 79, and the coil 82 are referred to as a detection part, and by these, the degree of expansion and contraction of the elastic body can be detected. The conversion rod 76 and the mountain-shaped portion 78 are collectively referred to as a conversion member 83, and the expansion and contraction of the spring 77 in the rotational direction is converted into movement in the direction of the axle 68.
[0074]
Next, the power system diagram with the above configuration will be described with reference to FIG.
[0075]
First, the human power drive system will be described. The human power given by the pedal 5 is transmitted to the rear sprocket 67 by the chain 17 and rotates the rear wheel 11 through the rotating plate 74 and the spring 77. Next, the electric drive system will be described. The amount of expansion and contraction of the spring 77, that is, the rotational movement distance of the rotary plate 74 is converted into movement in the direction of the axle 68 by the conversion member 83, and the ring 79 moves with the movement. To do. This movement of the ring 79 is converted into a change in inductance of the coil 82 and input to the control board 66 as an electrical signal. The control board 66 is built in the fixed casing 47. Then, a signal of the coil 82 is inputted to the control board 66, and a drive signal is outputted so that the motor 36 is rotated based on the signal. Then, the output of the motor 36 is decelerated by the planetary roller reduction mechanism 54, and the rear wheel 11 rotates through the first pulley 56. The ratio of the human driving force and the electric driving force in this control is 1: 1, and assistance by the motor 36 is performed.
[0076]
Further, the control board 66 is connected to the micro switch 24 provided on the stand 19 to detect the up-and-down state of the stand 19.
[0077]
Next, the operation in the above-described configuration will be described with reference to FIGS.
[0078]
The flowchart in FIG. 11 shows only the setting of the output value of the electric driving force.
[0079]
When the bicycle descends from the stand 19 and stops, the state where the bicycle is descending is input to the control circuit 34 (S1). When the stand 19 continues in the lowered state, the electric driving force K is zero, that is, the operation by the electric driving force is not performed (S2). Here, when the stand 19 is raised, the signal A from the torque detector 45 is input (S3), and it is determined whether the input signal from the torque detector 45 and the output signal to the drive unit 15 are the same. (S4). If they are the same, it is determined that the pedal 5 is not depressed, and it is determined again whether the stand 19 is raised (S1). If the input signal from the torque detection unit 45 and the output signal to the drive unit 15 are different, the process proceeds to the next. Next, when the input signal from the torque detection unit 45 and the output signal to the drive unit 15 are different, for example, when the input signal of the human power torque is larger, it is determined that the pedal 5 is stepped on with force applied, The output signal to the drive unit 15 is gradually increased one by one (S6). After incrementing by 1, when returning to the beginning of this routine and passing through this portion again, 1 is added to the output signal 1 at the time of first passing to become 2. If this state continues, the speed will gradually increase with time. A so-called soft start is performed.
[0080]
Next, after the start of traveling, the signal from the torque detection unit 45 is compared with the signal to the drive unit 15 (S5), and when the force to step on the pedal 5 becomes weak, the input from the torque detection unit 45 and the drive unit 15 (S7).
[0081]
In addition, it is determined whether or not the stand 19 is always raised during traveling (S1). If the stand 19 is lowered during traveling, there is a risk that the stand 19 and the ground may come into contact with each other. The electric driving force K is set to zero (S2), and the electric driving force is stopped.
[0082]
The flowchart described above is shown in signal input / output states as shown in FIG.
[0083]
This timing chart shows a signal from the micro switch 24 at the top, and shows a state where the stand 19 is lowered and the micro switch 24 is turned on in the presence of the signal. The next signal is a timing chart in which a solid line indicates an input signal from the torque detection unit 45 and a broken line indicates an output signal to the drive unit 15. Here, a plurality of semicircles are described upward, and one cycle of the semicircle indicates a change in the force of the human-powered torque of the half rotation of the pedal 5. The higher the waveform height, the greater the driving force the user is traveling.
[0084]
First, the position of the stand 19 is raised, and when the pedal 5 is depressed and a signal of human driving force is input from the torque detector 45, the electric driving signal gradually rises accordingly (A). In this case, the magnitude of the manpower torque and the output signal to the drive unit 15 are the same and overlap, so only the solid line is shown. When the driving force is reduced, for example, when the running is finished, the electric drive signal is also reduced and the driving is finished (B). When the stand 19 is lowered, a signal indicating that the stand 19 is lowered is input (C).
[0085]
At this time, when the pedal 5 is depressed and human power driving force is input, a signal from the torque detector 45 is input to the control circuit 34 (D). The reason why the signal from the torque detection unit 45 described in the solid line at this time is not semicircular but is moving slightly is that the vehicle is stopped by a brake operation or the like while the pedal 5 is depressed. When the stand 19 is raised in this state (E), the electric drive signal gradually rises to the same drive force as the human drive force, and the input signal from the torque detector 45 within one cycle of the rotation of the pedal 5. (F). This portion shows the routine of S6 in the above-described flowchart, and the follow-up to the instruction drive output is faster than the soft start of the first embodiment, and the follow-up is performed within one cycle of the pedal. Then, normal traveling is started, but when the stand 19 is lowered during traveling, the electric drive signal stops despite the torque signal from the torque detector 45, and the traveling by the electric driving force is stopped (G ).
[0086]
As described above, since the control circuit 34 for stopping the operation of the drive unit 15 is provided when the stand 19 is lowered, when the stand 19 is lowered and stopped, the pedal 5 is stepped on to be driven manually. Since the drive unit 15 does not operate even if force is generated, it does not start suddenly against the user's intention and is very safe. Further, when the stand 19 is lifted from the lowered position, the signal output to the drive unit 15 is gradually approached from the small value to the same value as the value of the torque detection unit 45 over time, so that the pedal 5 is depressed. Even if the stand 19 is raised, it does not start suddenly and is safe. Furthermore, when running with the stand 19 lowered, there is no output from the drive unit 15 even if the pedal 5 is subjected to human power. The person notices that the stand 19 is lowered, and can prevent danger.
[0087]
【The invention's effect】
The present invention includes a vehicle main body provided with an electric drive unit using a motor as a drive source, a human power drive unit using human power as a drive source, and a stand that can be raised and lowered to support the standing of the main body while the vehicle main body is stopped. Since there is a control unit that stops the operation of the electric drive unit when the stand is lowered, an elevating detection unit that detects the lift state of the stand is provided. Since the drive unit does not operate, the vehicle does not start suddenly against the user's intention, and there are effects such as being very safe.
[0088]
And when traveling with the stand lowered, only the driving by the human drive unit can be done, so the user can know the descent of the stand by feeling the weight of the pedal while traveling, and there is a danger. Can be prevented.
[0089]
In addition, an accelerator that manipulates the magnitude of the output of the electric drive unit is provided, and when the stand rises from the lowered position, the signal output to the electric drive unit is gradually made closer to the accelerator instruction value from a small value over time. Since it is equipped with a soft start section, it does not start suddenly even if the stand is raised with the accelerator operated, and it is safe. In addition, when driving with the stand lowered, there is no output from the drive unit even if the accelerator is operated, so the user can notice that the stand is down and prevent danger etc. Play.
[0090]
Furthermore, a torque detection unit for detecting the driving force of the human power drive unit is provided, and the electric drive unit is operated based on the signal of the torque detection unit by the control circuit, and when the stand is raised from the lowered position, the electric drive unit is connected to the electric drive unit. Since it has a soft start part that gradually brings the signal output from a small value to a human driving force over time, when the stand rises from the lowered position, the signal output to the driving part is small over time Since it gradually approaches the same value as the value of the torque detector from the value, even if the stand is raised with the pedal depressed, it does not start suddenly and is safe. Furthermore, when running with the stand lowered, there is no output from the drive unit even if the pedal is subjected to human power, so the user can notice that the stand is down and prevent danger. .
[Brief description of the drawings]
FIG. 1 is a block diagram of a control circuit showing a first embodiment of the present invention.
FIG. 2 is an exploded perspective view showing the structure of the accelerator.
FIG. 3 is a side view of the main body.
FIG. 4 is a side view of the stand.
FIG. 5 is a flowchart showing the operation of the stand and the accelerator circuit.
FIG. 6 is a timing chart showing output signals of the stand and the accelerator circuit.
FIG. 7 is a block diagram of a control circuit showing a second embodiment of the present invention.
FIG. 8 is a diagram of the same power system.
FIG. 9 is a side sectional view of the drive unit.
FIG. 10 is a plan view of the drive unit.
FIG. 11 is a flowchart showing the operation of the stand and the torque detector.
FIG. 12 is a timing chart showing output signals of the stand and the torque detector.
[Explanation of symbols]
36     motor
        15 Drive unit (electric drive unit)
5 pedals
        17 chain
        67 Rear sprocket
1 Body (vehicle body)
        19 Stand
        24 Micro switch (Elevation detector)
34 Control circuit
        25 Accelerator
        45 Torque detector

Claims (2)

A vehicle main body provided with an electric drive unit using a motor as a drive source, a human power drive unit using human power as a drive source, an accelerator for operating the output magnitude of the electric drive unit, and while the vehicle main unit is stopped A stand that can be raised and lowered to support the standing of the main body, provided with a lift detection unit for detecting the lift state of the stand, and provided with a control circuit for stopping the operation of the electric drive unit when the stand is lowered. When the accelerator is operated and the stand is lifted from the lowered position, the control circuit gradually increases the signal output to the electric drive unit from a small value to a command value of the accelerator over time. A vehicle with auxiliary power, characterized by having a soft start section . A vehicle main body provided with an electric drive unit using a motor as a drive source, a human power drive unit using human power as a drive source, a torque detection unit for detecting the drive force of the human drive unit, and the vehicle main unit being stopped And an elevating detection unit for detecting the elevating state of the stand, and when the stand is lowered, the operation of the electric drive unit is stopped, A control circuit is provided for controlling the electric drive unit based on a signal from the torque detection unit when the lift is raised, and the control circuit is configured so that the stand is in the lowered position in a state where the driving force is applied to the human power drive unit. A vehicle with auxiliary power, comprising: a soft start portion that gradually brings the signal output to the electric drive portion from a small value to a human drive force as time elapses .

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