JP5207769B2 - Automatic shifting method for electric bicycle - Google Patents

Description

  The present invention relates to an automatic transmission method for an electric bicycle equipped with an automatic transmission device, and more particularly to a shift-down control method.

  Conventionally, in general, an electric bicycle generates auxiliary power corresponding to a pedaling force by an auxiliary electric motor, and transmits a resultant force of the pedaling force and the auxiliary power to a rear axle to rotationally drive a rear wheel. Some of such electric bicycles are provided with an automatic transmission.

  In an electric bicycle equipped with such an automatic transmission device, the deceleration operation and the acceleration operation are automatically performed. When the deceleration operation is automatically performed, if there is a driving force exceeding a certain value, the automatic transmission There was a problem that an excessive load was applied to the apparatus, and the deceleration operation could not be performed smoothly. The following methods are known as automatic transmission methods for solving such problems.

  That is, as shown in FIG. 11, the speed and the pedaling force are detected, and the optimum shift position is calculated according to the detected speed and the pedaling force (step S1). It is determined whether or not the optimum shift position and the current shift position are the same (step S2). If they are the same, the optimum shift position is calculated again (step S1). Is a deceleration operation (step S3).

  If the shift operation is a deceleration operation, the control unit waits until the pedaling force value falls below a certain value (step S4). When the pedaling force value falls below a certain value, the control device sends a shift change instruction signal ( A deceleration signal) is transmitted to the actuator motor to drive the actuator motor (step S5). When the actuator motor is driven, the shift change device (transmission) is actuated to perform a desired deceleration operation. In this case, the deceleration operation is performed in accordance with the timing at which the pedal force decreases, so that a smooth deceleration operation is performed. Made stable.

The automatic transmission method as described above is disclosed in Patent Document 1 below.
JP 2001-10581 A

  However, in the above-described conventional format, the deceleration operation is performed in accordance with the timing at which the pedal force decreases, but it is unclear what kind of deceleration operation is performed at what timing. That is, as shown in step S4, when the control device transmits a shift change instruction signal to the actuator motor when the pedaling force value falls below a certain value, the control device transmits the shift change instruction signal to the actuator motor. After that, there is a slight time difference (time shift) from when the shift change device is actually operated to when the deceleration operation is executed.

  Accordingly, when the timing is shifted due to the time difference as described above and the pedaling force value increases beyond a certain value, the transmission actually starts to operate, and the deceleration operation is executed near the peak where the pedaling force value becomes the largest. There is a risk of it. When the deceleration operation is executed with the timing shifted in this way, an excessive load is applied to the shift change device, which causes a problem that the deceleration operation cannot be performed smoothly.

  The present invention takes into account the time difference from when the control device transmits a deceleration signal to the actuator until the transmission is actually operated and the deceleration operation is executed. It aims at providing the automatic transmission method of a bicycle.

  In order to achieve the above object, an automatic shifting method for an electric bicycle according to the first aspect of the present invention detects a stepping torque acting on a crankshaft rotated by a pedal, and calculates a moving average torque based on the detected stepping torque. When the moving average torque exceeds a predetermined torque threshold, the first peak of the depression torque detected immediately after that is detected, and when the first peak of the depression torque is detected, the control device decelerates. A signal is transmitted to the actuator to drive the actuator to start deceleration, and in the valley between the first peak of the stepping torque and the second peak detected next, the transmission moves to the current gear stage. The gearbox is in the middle of switching to be switched from the first gear position to the first gear position, and before reaching the second peak of the stepping torque, the transmission It is intended to end the deceleration.

  According to this, when the first peak of the depression torque is detected, the control device sends a deceleration signal to the actuator, so that the transmission starts to operate, and after a slight time difference, the first peak of the depression torque. In the valley between the second peak and the second peak, the transmission is in the process of being switched from the current shift stage to the first reduction stage, and before reaching the second peak of the depression torque, Deceleration operation ends.

  As described above, according to the present invention, the deceleration operation is performed in consideration of the time difference (time lag) from when the control device transmits a deceleration signal to the actuator until the transmission is actually operated and the deceleration operation is executed. Since the control is performed, the deceleration operation is performed at the timing when the load applied to the transmission is reduced, and the smooth deceleration operation can be performed more reliably.

In order to achieve the above object, the first aspect of the present invention includes an auxiliary electric motor that generates auxiliary power corresponding to the pedaling force acting on the pedal, and an automatic transmission.
The automatic transmission device is an automatic transmission method for an electric bicycle having a transmission that can be switched to a plurality of shift stages with different transmission ratios and an actuator that operates the transmission,
Detecting the stepping torque acting on the crankshaft rotated by the pedal,
Based on the detected stepping torque, a moving average torque that is an integrated value of the stepping torque within a predetermined range of time at a time point that is a predetermined time backward from the present time is obtained,
When the moving average torque is equal to or greater than a predetermined torque threshold, the first peak of the depression torque detected immediately after is detected,
When the first peak of the depression torque is detected, the control device transmits a deceleration signal to the actuator to drive the actuator, and starts deceleration.
In the valley between the first peak of the stepping torque and the second peak detected next, the transmission is in the middle of switching to be switched from the current gear to the gear on the one-speed reduction side,
The speed reduction operation of the transmission is completed before the second peak of the depression torque is reached.

  According to this, when the first peak of the depression torque is detected, the control device sends a deceleration signal to the actuator, so that the transmission starts to operate, and after a slight time difference, the first peak of the depression torque. In the valley between the second peak and the second peak, the transmission is in the process of being switched from the current shift stage to the first reduction stage, and before reaching the second peak of the depression torque, Deceleration operation ends.

  Thus, since the control device controls the deceleration operation in consideration of the time difference (time lag) from when the deceleration signal is transmitted to the actuator until the transmission actually operates and the deceleration operation is executed, A deceleration operation is performed at the timing when the load applied to the transmission is reduced, and a smooth deceleration operation can be performed more reliably.

  According to the second aspect of the present invention, when the traveling speed is detected and the detected traveling speed is not more than a predetermined speed threshold and the moving average torque is not less than the predetermined torque threshold, the stepping torque detected immediately after that is detected. The first peak is detected.

  According to this, even if the moving average torque is equal to or greater than a predetermined torque threshold, if the detected traveling speed is higher than the predetermined speed threshold, the speed reduction operation of the transmission is not performed. Therefore, in order to increase the traveling speed of the bicycle, when the pedaling force against the pedal is increased to suddenly increase the rotational speed of the crankshaft and the traveling speed of the bicycle is made higher than a predetermined speed threshold, the speed reduction operation of the transmission suddenly occurs. Is performed, and a problem that the traveling speed suddenly decreases against the passenger's intention can be prevented.

When the third invention detects the first peak of the depression torque, the auxiliary motor is stopped,
The auxiliary motor is operated when the speed reduction operation of the transmission is completed.
Thereby, since the load by the auxiliary motor is not applied to the transmission by stopping the auxiliary motor, the deceleration operation is performed in a state where the load applied to the transmission is further reduced. Therefore, the smooth deceleration operation is more reliably performed. It can be carried out.

In the fourth aspect of the present invention, when it is detected that the transmission has been switched from the current shift speed to the shift speed on the one-speed reduction side, it is determined that the speed reduction operation of the transmission has been completed.
Hereinafter, embodiments of the present invention will be described with reference to the drawings.

  As shown in FIGS. 1 to 3, reference numeral 11 denotes an electric bicycle. The electric bicycle 11 includes a frame 21, a rear wheel hub shaft 22 fixed to the rear end portion of the frame 21, front and rear wheels 26 and 27, and Acting on the auxiliary motor 12 for generating auxiliary power, the battery 13 for supplying power to the auxiliary motor 12, the automatic transmission 14, the pedal 15, the crankshaft 16 rotated by the pedal 15, and the crankshaft 16 A torque detector 17 (for example, a magnetostrictive sensor or the like) that detects the stepping torque TOa, a speed detector 18 that detects a traveling speed, a control device 19, and a display device 20 are provided.

  The automatic transmission 14 includes an internal transmission 23 (an example of a transmission) that can be switched to three speeds (a plurality of gear speeds) having different speed ratios, an actuator 24 that operates the internal transmission 23, and an internal transmission 23. And an interlocking mechanism 25 provided between the actuator 24 and the actuator 24.

  As shown in FIG. 4, the internal transmission 23 is a system that shifts gears by changing a gear incorporated in the rear wheel hub, and includes a sun gear 28 fixed to the rear wheel hub shaft 22, and a rear wheel. A free wheel 29, a controller 30, and a planetary arm 31 that are rotatably fitted to the hub shaft 22, an internal gear 32 that is rotatably fitted to the free wheel 29, the controller 30, and the planetary arm 31, and a planetary arm 31. A plurality of planetary gears 33 that mesh with the sun gear 28 and the internal gear 32 and a hub shell 34 that is rotatably fitted to the internal gear 32.

  The free wheel 29 has a free wheel one-way clutch 36 that can be freely engaged and disengaged with respect to the internal gear 32. The planetary arm 31 has a planetary arm one-way clutch 37 that is detachable with respect to the hub shell 34. The internal gear 32 has an internal gear one-way clutch 38 that can be engaged and disengaged with respect to the hub shell 34.

The spoke 40 of the rear wheel 27 is connected to the hub shell 34. A chain 42 is wound between the free wheel 29 and the sprocket 41 of the gear crank.
The controller 30 is connected to the speed change rod 39, and is movable in the axial direction of the rear wheel hub shaft 22 together with the speed change rod 39 by pushing and pulling the speed change rod 39. First to third switching positions P1 to P3 are set on the axial center of the rear wheel hub shaft 22. As shown in FIG. When moved to the first switching position P1, the internal transmission 23 is switched to the first gear position having the smallest gear ratio, and when moved to the third switching position P3 as shown in FIG. When the gear is switched to the third gear with a large ratio and moved to the second switching position P2, as shown in FIG. 4 (b), the second gear with the intermediate gear ratio between the first gear and the third gear is selected. Switched.

  As shown in FIG. 4A, when the controller 30 moves to the third switching position P3, the free wheel 29, the controller 30, and the planetary arm 31 are directly connected, and the speed increasing path is increased by the planetary gear 33. 55 is formed. At this time, the rotational angular velocity of the internal gear 32 (hub shell 34) is higher than that of the planetary arm 31, so that the planetary arm one-way clutch 37 becomes free.

  As shown in FIG. 4B, when the controller 30 moves to the second switching position P2, the controller 30 is detached from the planetary arm 31, and the rotational angular velocities of the free wheel 29 and the internal gear 32 (hub shell 34) are the same. A normal path 56 is formed. At this time, the rotational angular velocity of the internal gear 32 (hub shell 34) is higher than that of the planetary arm 31, so that the planetary arm one-way clutch 37 becomes free.

  As shown in FIG. 4C, when the controller 30 moves to the first switching position P1, the controller 30 comes into contact with the internal gear one-way clutch 38, the internal gear one-way clutch 38 comes off from the hub shell 34, and the deceleration path 57 is formed.

The internal transmission 23 incorporates a spring (biasing member: not shown) that urges the transmission rod 39 to push out in the downshifting direction A.
As shown in FIGS. 2 and 5, the actuator 24 includes a speed change motor 24a having a speed reduction mechanism. Further, the interlocking mechanism 25 shifts the pinion 45 provided on the rotating shaft 24b of the speed change motor 24a, the rack 46 meshing with the pinion 45, and the speed change rod 39 in the direction of shifting up against the biasing force of the spring. A bell crank device 47 to be pushed into B and a transmission wire 48 are provided.

  The actuator 24 and the rack 46 are supported on the frame 21 side, and the rack 46 moves in the length direction (front-rear direction) of the transmission wire 48 according to the rotation of the rotating shaft 24b. The bell crank device 47 includes an attachment plate 50 attached to the chain stay 49 of the frame 21 and a bell crank member 52 rotatably provided on the attachment plate 50 via the longitudinal axis 51. . The transmission wire 48 is connected between the rack 46 and the bell crank member 52.

  When the rotating shaft 24b of the speed change motor 24a rotates in one direction b1, the speed change wire 48 is pulled in one direction b2, the bell crank member 52 rotates in one direction b3, and the speed change rod 39 is shifted up. Pushed in direction B. As a result, the gears are shifted up in the order of first gear → second gear → third gear.

  Further, when the rotating shaft 24b of the speed change motor 24a rotates in the reverse other direction a1, the speed change wire 48 is loosened in the other direction a2, and the speed change rod 39 is shifted down by the urging force of a spring (not shown). Extruded in direction A. As a result, the gears are shifted down in the order of 3rd gear → 2nd gear → 1st gear.

  The speed change motor 24a is provided with a rotation angle detector 54 (pulse encoder or the like) for detecting the rotation angle (or the number of rotations) of the rotary shaft 24b. Since the rotation angle (or the number of rotations) of the rotation shaft 24b of the speed change motor 24a corresponds to the first to third switching positions P1 to P3 of the controller 30, the rotation angle detector 54 causes the rotation shaft 24b to rotate. By detecting the rotation angle (or the number of rotations), it is determined which of the first to third switching positions P1 to P3 the controller 30 has moved to, and based on this, the internal transmission 23 is set to the first gear. It is possible to detect which of the first to third gears is switched to.

  That is, as shown in FIG. 6, when the rotation angle detector 54 detects the first rotation angle C1 (for example, C1 = 90 °), the controller 30 moves to the first switching position P1 and shifts to the first gear. When it is detected that the rotation has been switched and the rotation angle detector 54 detects the second rotation angle C2 (for example, C2 = 180 °), the controller 30 moves to the second switching position P2 and switches to the second gear. When the rotation angle detector 54 detects the third rotation angle C3 (for example, C3 = 270 °), the controller 30 moves to the third switching position P3 and is switched to the third gear. Is detected.

  The display device 20 displays the detected gear position of the internal transmission 23, the remaining amount of the battery 13, and the like. As shown in FIG. 3, the control device 19 includes an auxiliary motor control unit 19a and an automatic transmission control unit 19b.

  The auxiliary motor controller 19a controls the auxiliary motor 12 based on the depression torque data detected by the torque detector 17, and transmits the depression torque data to the automatic transmission controller 19b.

  The automatic transmission control unit 19b includes a stepping torque data transmitted from the auxiliary motor control unit 19a, a travel speed data detected by the speed detector 18, and a speed change motor detected by the rotation angle detector 54. The actuator 24 and the display device 20 are controlled based on the rotation angle data of the rotating shaft 24b of 24a.

  The automatic transmission control unit 19b transmits a deceleration signal to the actuator 24 when shifting down, and transmits a speed increasing signal to the actuator 24 when shifting up, and stops when the actuator 24 is stopped. A signal is transmitted to the actuator 24, and an auxiliary motor stop signal for stopping the auxiliary motor 12 and an auxiliary motor drive signal for driving the auxiliary motor 12 are transmitted to the auxiliary motor control unit 19a.

  Next, an automatic transmission method (shift-down control method) of the electric bicycle 11 having the above-described configuration will be described with reference to the graphs of FIGS. 7 to 9 and the flowchart of FIG.

  When the occupant is driving the electric bicycle 11, a stepping torque TOa (see a solid line in FIG. 7) acting on the crankshaft 16 rotated by the pedal 15 is detected by the torque detector 17. Data of the detected depression torque TOa is transmitted to the auxiliary motor controller 19a, and further transmitted from the auxiliary motor controller 19a to the automatic transmission controller 19b.

The auxiliary motor controller 19a drives the auxiliary motor 12, and generates an auxiliary torque TOb (see the dotted line in FIG. 7) having the same magnitude as the detected stepping torque TOa.
The automatic transmission control unit 19b obtains a moving average torque TOc (see the two-dot chain line in FIG. 7) based on the detected stepping torque TOa (step -1). As shown in FIG. 8, the moving average torque TOc is a stepping torque TOa within a predetermined range of time t2 (for example, 0.4 seconds) at a time point that is a predetermined time t1 (for example, 0.5 seconds) from the current time. It is an integral value (shaded area). Here, the time t2 within the predetermined range is equal to or less than the predetermined time t1 (t2 ≦ t1).

  Further, the traveling speed of the electric bicycle 11 is detected by the speed detector 18 (step-2). The automatic transmission control unit 19b determines whether or not the detected traveling speed is equal to or lower than a predetermined speed threshold (step -3). If the detected traveling speed is higher than the predetermined speed threshold, the process returns to the step (step -1).

  If it is equal to or lower than the predetermined speed threshold, the automatic transmission control unit 19b determines whether or not the moving average torque TOc is equal to or higher than the predetermined torque threshold TOd (see FIG. 7) (step -4). If it is lower than the threshold value TOd, the procedure returns to (Step-1).

  Further, as shown in the point (A) of FIG. 7, when the moving average torque TOc is equal to or greater than a predetermined torque threshold value TOd, the automatic transmission control unit 19b determines that the stepping torque TOa detected immediately thereafter is 1 It is determined whether the first peak P1 has been detected (step -5). As shown in FIG. 9, the automatic transmission control unit 19b compares three data of the detected stepping torque TOa, and the stepping torque value TOa2 detected second is the first stepping detected. If the torque value TOa1 is greater than or equal to the torque value TOa1 and the stepping torque value TOa3 detected third is smaller than the stepping torque value TOa2 detected second, it is determined that the peak P1 of the stepping torque TOa has been detected.

  When the first peak P1 is detected, the automatic transmission control unit 19b detects the current state of the internal transmission 23 based on the rotation angle of the rotation shaft 24b of the transmission motor 24a detected by the rotation angle detector 54. A shift speed is obtained, and it is determined whether or not the current shift speed is the first speed (step -6).

  When the current gear position is, for example, the third gear position, the automatic transmission control unit 19b transmits a deceleration signal to the actuator 24 and the auxiliary motor control unit 19a as shown in FIG. An auxiliary motor stop signal is transmitted (step -7).

  As a result, the auxiliary motor 12 stops and the auxiliary torque TOb generated from the auxiliary motor 12 becomes zero. Further, as shown in FIG. 6, the rotation shaft 24b of the speed change motor 24a of the actuator 24 is changed from the third rotation angle C3 (corresponding to the third gear) to the second rotation angle C2 (corresponding to the second gear). It rotates in the direction a1 (step-8). As a result, as shown in FIG. 2, the speed change wire 48 is loosened in the other direction a2, and the speed change rod 39 is pushed out in the downshift direction A by the urging force of the spring (not shown). As shown, the controller 30 is disengaged from the planetary arm 31 and moves from the third switching position P3 to the second switching position P2, and is shifted down from the third gear to the second gear.

  Thus, when the first peak P1 of the stepping torque TOa is detected, the automatic transmission control unit 19b transmits a deceleration signal to the actuator 24, as shown in FIG. In a valley 59 between the first peak P1 of the stepping torque TOa and the second peak P2 detected next, after a slight time difference t3, the internal transmission 23 is set to the third speed (current speed change). Stage) to the second speed stage (shift stage on the first speed reduction side). In this case, the state in the middle of switching is a state at the moment when the controller 30 is located between the third switching position P3 and the second switching position P2 and is disengaged from the planetary arm 31.

  The automatic transmission control unit 19b determines whether the rotation angle of the rotation shaft 24b detected by the rotation angle detector 54 has reached the second rotation angle C2 corresponding to the second switching position P2 (step − 9) When the second rotation angle C2 is reached, the shift completion signal transmitted from the actuator 24 determines that the gear has been shifted down from the third gear to the second gear, transmits a stop signal to the actuator 24, An auxiliary motor drive signal is transmitted to the auxiliary motor controller 19a (step -10). As a result, the speed-changing motor 24a of the actuator 24 is stopped and, as indicated by a point (d) in FIG. 7, before the second peak P2 of the stepping torque TOa is reached, the second speed 2 While the deceleration operation to the high speed is completed, the auxiliary motor 12 is activated to generate the auxiliary torque TOb (step-11).

  In Step-6, when the current gear is, for example, the second gear, the automatic transmission control unit 19b similarly sends a deceleration signal to the actuator 24, as indicated by a point (b) in FIG. At the same time, an auxiliary motor stop signal is transmitted to the auxiliary motor controller 19a (step -7).

  As a result, the auxiliary motor 12 stops and the auxiliary torque TOb generated from the auxiliary motor 12 becomes zero. In addition, as shown in FIG. 6, the speed change motor 24a of the actuator 24 rotates from the second rotation angle C2 (corresponding to the second gear) to the first rotation angle C1 (corresponding to the first gear) in the other direction a1. (Step-8). As a result, as shown in FIG. 2, the speed change wire 48 is loosened in the other direction a2, and the speed change rod 39 is pushed out in the downshift direction A by the urging force of the spring (not shown). As shown in FIG. 2, the controller 30 moves from the second switching position P2 to the first switching position P1 and comes into contact with the internal gear one-way clutch 38. Shift down to 1st gear.

  At this time, as indicated by a point (c) in FIG. 7, a valley 59 between the first peak P1 of the stepping torque TOa and the second peak P2 detected after that is obtained after a slight time difference t3. In FIG. 3, the internal transmission 23 is in the middle of switching to be switched from the second gear (current gear) to the first gear (the gear on the one-speed reduction side). In this case, the state in the middle of switching is a state at the moment when the controller 30 is positioned between the second switching position P2 and the first switching position P1 and contacts the internal gear one-way clutch 38.

  The automatic transmission control unit 19b determines whether the rotation angle of the rotation shaft 24b detected by the rotation angle detector 54 has reached the first rotation angle C1 corresponding to the first switching position P1 (step − 9) When the first rotation angle C1 is reached, the shift completion signal transmitted from the actuator 24 determines that the gear has been shifted down from the second gear to the first gear, transmits a stop signal to the actuator 24, An auxiliary motor drive signal is transmitted to the auxiliary motor controller 19a (step -10). As a result, the speed-changing motor 24a of the actuator 24 is stopped and, as indicated by a point (d) in FIG. 7, before the second peak P2 of the stepping torque TOa is reached, the first speed from the second speed of the internal transmission 23 is increased. While the deceleration operation to the high speed is completed, the auxiliary motor 12 is activated to generate the auxiliary torque TOb (step-11).

  In this way, taking into account the time difference t3 (time lag) from when the automatic transmission control unit 19b transmits the deceleration signal to the actuator 24 until the internal transmission 23 actually operates and the deceleration operation is executed, Since the deceleration operation is controlled, the deceleration operation is performed at the timing when the load applied to the internal transmission 23 is reduced, and the smooth deceleration operation can be performed more reliably.

In Step-6, when the current shift speed is, for example, the first speed, a further downshift cannot be performed, and thus a series of control is terminated.
Moreover, in the said step-1, the state of a road surface can be detected to some extent by calculating | requiring the moving average torque TOc. For example, when traveling on a steep uphill, the moving average torque TOc increases.

  Further, if the detected traveling speed is higher than the predetermined speed threshold in Steps 3 and 4, the deceleration operation of the internal transmission 23 is performed even if the moving average torque TOc becomes equal to or higher than the predetermined torque threshold TOd. I will not. Accordingly, in order to increase the traveling speed of the electric bicycle 11, the pedal force applied to the pedal 15 is increased to suddenly increase the rotational speed of the crankshaft 16, and the traveling speed of the electric bicycle 11 is made higher than a predetermined speed threshold. Thus, it is possible to prevent a problem that the speed reduction operation of the internal transmission 23 is suddenly performed and the traveling speed is suddenly reduced against the occupant's intention.

  Further, when the first peak P1 of the stepping torque TOa is detected in Steps-5 and 7, the auxiliary motor 12 is stopped, and when the deceleration operation of the internal transmission 23 is completed in Step-11, the auxiliary motor 12 is stopped. Since the electric motor 12 operates, the deceleration operation is performed in a state where the load by the auxiliary electric motor 12 is not applied to the internal transmission 23. Therefore, the deceleration operation is performed in a state where the load applied to the internal transmission 23 is further reduced, and the smooth deceleration operation can be performed more reliably.

The above is the downshift control method, and the upshift control method is performed as follows, for example.
(1) The acceleration is obtained by differentiating the moving average value of the traveling speed detected by the speed detector 18 to detect the acceleration / deceleration state of the electric bicycle 11.

  (2) When the traveling state of the electric bicycle 11 is the acceleration state, the automatic transmission control unit 19b transmits an acceleration signal to the actuator 24 when the detected current traveling speed is equal to or higher than the first speed set value. To do.

  Thereby, for example, when the current shift speed is the first speed, the rotation shaft 24b of the speed change motor 24a of the actuator 24 is unidirectional from the first rotation angle C1 to the second rotation angle C2, as shown in FIG. Rotate to b1. As a result, as shown in FIG. 2, the speed change wire 48 is pulled in one direction b2, and the speed change rod 39 is pushed in the upshift direction B against the biasing force of the spring, as shown in FIG. Thus, the controller 30 moves from the first switching position P1 to the second switching position P2, and the internal transmission 23 is switched from the first speed to the second speed.

  Further, when the current shift speed is the second speed, as shown in FIG. 6, the rotation shaft 24b of the speed change motor 24a of the actuator 24 moves from the second rotation angle C2 to the third rotation angle C3 in one direction b1. Rotate. As a result, as shown in FIG. 2, the speed change wire 48 is pulled in one direction b2, and the speed change rod 39 is pushed in the upshift direction B against the biasing force of the spring, as shown in FIG. Thus, the controller 30 moves from the second switching position P2 to the third switching position P3, and the internal transmission 23 is switched from the second speed to the third speed.

Note that when the current gear stage is at the third gear speed, no further up-shifting is possible, and the series of controls is terminated.
(3) Also, when the traveling state of the electric bicycle 11 is not the acceleration state but is traveling at a constant speed, the detected current traveling speed is equal to or greater than the second speed setting value and the calculated movement When the average torque TOc becomes equal to or less than a predetermined torque set value, the automatic transmission control unit 19b transmits an acceleration signal to the actuator 24.

  Thereby, for example, when the current shift speed is the first speed, the rotation shaft 24b of the speed change motor 24a of the actuator 24 is unidirectional from the first rotation angle C1 to the second rotation angle C2, as shown in FIG. Rotate to b1. As a result, as shown in FIG. 2, the speed change wire 48 is pulled in one direction b2, and the speed change rod 39 is pushed in the upshift direction B against the biasing force of the spring, as shown in FIG. Thus, the controller 30 moves from the first switching position P1 to the second switching position P2, and the internal transmission 23 is switched from the first speed to the second speed.

  Further, when the current shift speed is the second speed, as shown in FIG. 6, the rotation shaft 24b of the speed change motor 24a of the actuator 24 moves from the second rotation angle C2 to the third rotation angle C3 in one direction b1. Rotate. As a result, the speed change wire 48 is pulled in one direction b2, and the speed change rod 39 is pushed in the upshift direction B against the urging force of the spring. As shown in FIG. Moving from the second switching position P2 to the third switching position P3, the internal transmission 23 is switched from the second speed to the third speed.

Note that when the current gear stage is at the third gear speed, no further up-shifting is possible, and the series of controls is terminated.
(4) Further, when the traveling state of the electric bicycle 11 is a deceleration state, the automatic transmission control unit 19b does not transmit a speed increase signal to the actuator 24, and the upshift is not performed.

  In the above-described embodiment, the three-stage internal transmission 23 is described as an example of the transmission. However, the transmission is not limited to three stages, and may be a plurality of stages other than three stages. Moreover, it is not limited to the internal transmission 23, You may use an external transmission.

  In the above-described embodiment, the rotation angle detector 54 detects the rotation angle (or the number of rotations) of the rotation shaft 24b of the speed change motor 24a, so that the internal transmission 23 is in any of the first to third speed stages. However, by detecting the position of the tip of the speed change rod 39, the internal transmission 23 is switched to the first speed to the third speed. May be detected.

  In the above embodiment, as shown in FIG. 8, the moving average torque TOc is within a predetermined range of time t2 (for example, 0.4 seconds) at a time point that is a predetermined time t1 (for example, 0.5 seconds) from the current time. However, in this case, the predetermined time t1 may be set to a predetermined time t2. That is, when t1 = t2, the moving average torque TOc is an integrated value (shaded portion) of the stepping torque TOa from the time point that is a fixed time t1 (for example, 0.5 seconds) back to the present time.

  The present invention relates to an automatic speed change method for an electric bicycle equipped with an automatic speed change device, and is particularly effective for a shift down control method.

Side view of an electric bicycle according to an embodiment of the present invention The top view of the automatic transmission of the same electric bicycle Same as above, block diagram of control system of automatic transmission of electric bicycle Sectional drawing which shows the switching operation | movement of the transmission of the automatic transmission of the same electric bicycle Schematic diagram showing the configuration of the interlocking mechanism of the electric bicycle automatic transmission The figure which shows the correspondence of the rotational angle of the rotating shaft of the actuator of the automatic transmission apparatus of an electric bicycle, and the gear stage of a transmission Same as above, a graph showing the automatic shifting method (shift down) of an electric bicycle Same as above, a graph showing the moving average torque in the automatic shifting method of an electric bicycle The figure explaining the method of detecting the peak of the depression torque in the automatic shifting method of the electric bicycle The flowchart showing the automatic shifting method (shift down) of the electric bicycle A flowchart showing a conventional automatic shifting method (shift down) of an electric bicycle

Explanation of symbols

DESCRIPTION OF SYMBOLS 11 Electric bicycle 12 Auxiliary motor 14 Automatic transmission 15 Pedal 16 Crankshaft 19 Control device 23 Internal transmission 24 Actuator 59 Valley TOa Depression torque TOc Moving average torque TOd Torque threshold t1 Fixed time t2 Time P1 in a predetermined range First peak P2 Second peak

Claims (4)

An auxiliary electric motor that generates auxiliary power corresponding to the pedaling force acting on the pedal, and an automatic transmission,
The automatic transmission device is an automatic transmission method for an electric bicycle having a transmission that can be switched to a plurality of shift stages with different transmission ratios and an actuator that operates the transmission,
Detecting the stepping torque acting on the crankshaft rotated by the pedal,
Based on the detected stepping torque, a moving average torque that is an integrated value of the stepping torque within a predetermined range of time at a time point that is a predetermined time backward from the present time is obtained,
When the moving average torque is equal to or greater than a predetermined torque threshold, the first peak of the depression torque detected immediately after is detected,
When the first peak of the depression torque is detected, the control device transmits a deceleration signal to the actuator to drive the actuator, and starts deceleration.
In the valley between the first peak of the stepping torque and the second peak detected next, the transmission is in the middle of switching to be switched from the current gear to the gear on the one-speed reduction side,
An automatic shifting method for an electric bicycle, characterized in that the speed reduction operation of the transmission is terminated before reaching the second peak of the depression torque. Detect travel speed,
When the detected traveling speed is equal to or lower than a predetermined speed threshold and the moving average torque is equal to or higher than a predetermined torque threshold, the first peak of the stepping torque detected immediately after that is detected. The method for automatically shifting an electric bicycle according to claim 1. When the first peak of the depression torque is detected, the auxiliary motor is stopped,
3. The method for automatically shifting an electric bicycle according to claim 1, wherein the auxiliary motor is operated when the speed reduction operation of the transmission is completed. 4. The method according to claim 1, wherein when it is detected that the transmission has been switched from the current gear position to a gear position on the one-speed reduction side, it is determined that the speed reduction operation of the transmission has been completed. 2. An automatic shifting method for an electric bicycle according to item 1.

Images