JP5508683B2 - Electric bicycle drive device - Google Patents

Description

  The present invention relates to an electric bicycle drive device including a one-way clutch in a human-powered drive system between a pedal crankshaft and a rear wheel drive chain sprocket.

  As a conventional driving device for an electric bicycle of this type, there is one described in Patent Document 1, for example. The electric bicycle drive device disclosed in Patent Document 1 can transmit both the force (human power) that the occupant depresses the pedal and the power of the motor corresponding to the magnitude of the human power to the rear wheel drive chain. It is configured. This drive device is comprised from the 1st casing which accommodated the human-powered drive system, and the 2nd casing which accommodated the motor drive system. In this drive device, the human power is transmitted from the pedal to the chain via a pedal crankshaft, a one-way clutch, and a chain sprocket.

The one-way clutch prevents the motor from rotating in the reverse direction when the pedal crankshaft is rotated in reverse, and the power or inertial force of the motor when the pedal crankshaft is stopped during traveling. Is equipped to prevent transmission to the pedal crankshaft.
The one-way clutch of a human-powered drive system disclosed in Patent Document 1 includes an inner part coupled to a pedal crankshaft and an outer part surrounding the inner part from the outside in the radial direction.

The outer portion is formed so as to penetrate the right side of the vehicle body of the first casing that houses the human power drive system, and the chain sprocket is fixed to the outside of the casing. That is, the output member of the conventional one-way clutch is constituted by this outer portion.
A portion of the outer portion that penetrates the casing is rotatably supported by the casing by a bearing. Further, the inner peripheral portion of the outer portion rotatably supports the pedal crankshaft by a bearing.
JP 2000-53069 A

  In the conventional electric bicycle drive device, further cost reduction is required. However, the electric bicycle drive device disclosed in Patent Document 1 has a limit in reducing costs. This is because the manufacturing cost of a one-way clutch for a human-powered drive system increases in the conventional electric bicycle drive device.

There are two possible reasons for the high manufacturing cost of the one-way clutch: a large number of manufacturing steps for the outer part and a low yield, and a high material cost for the outer part. Hereinafter, each of these two reasons will be described.
(1) Regarding the fact that there are many man-hours for manufacturing the outer part and a lot of material is wasted;
The outer portion is formed so that the outer diameter of the portion surrounding the inner portion from the radially outer side is relatively large. On the other hand, it is desirable that the portion for fixing the chain sprocket in the outer portion is formed so as to be as close as possible to the pedal crankshaft so that the outer diameter becomes relatively small in order to reduce the size. For this reason, this outer part turns into a stepped part from which an outer diameter changes large in an intermediate part.

In addition, the outer portion is required to have high strength in order to receive a force that expands from the inside to the outside by the claw member supported by the inner portion. A component that requires high strength, such as the outer portion, is generally formed by forging or sintering.
When the outer portion is formed into a rough shape by forging or sintering, machining is performed so that the bearing can be fitted to the outer peripheral portion and the inner peripheral portion.

  For example, when the outer part made of a stepped part is formed by forging, the corners of the small diameter part and the step part are formed round, so in order to press-fit a bearing into the small diameter part and make contact with the step part In addition, it is necessary to form a right angle corner by machining at the boundary portion between the small diameter portion and the step portion. In addition, in order to form this outer part by sintering, when the step between the large diameter part and the small diameter part is large, an extra step part of intermediate height is added to the outer peripheral part of the boundary part between the small diameter part and the large diameter part. In order to press the bearing into the small diameter part and make it contact with the step part of the large diameter part, this unnecessary step part of the outer peripheral part is machined after sintering. Need to be deleted. That is, in the conventional one-way clutch, after the outer portion is formed into a rough shape by forging or sintering, machining for enabling the bearing to be fitted is necessary. There were many. In addition, in this one-way clutch, material is wasted only by the machining allowance applied to the outer portion, and the yield is lowered.

(2) About the point that the material cost of the outer part becomes high;
As described above, the outer part of the one-way clutch is formed of a high-strength material because a large force is applied from the inner side toward the outer side in the radial direction by the claw member supported by the inner part. . Generally, high-strength materials are expensive. The outer portion described in Patent Document 1 is made of a material having a small diameter portion (a portion where the strength is not required as the larger diameter portion) to which the chain sprocket is fixed is integrally formed of an expensive material like the large diameter portion. Expenses are unnecessarily high.

  The present invention has been made to solve such problems, and an object of the present invention is to simplify the structure of a one-way clutch of a human-powered drive system so that the manufacture can be easily performed.

In order to achieve this object, an electric bicycle drive device according to the present invention includes a pedal crankshaft to which a pedal is connected and a rear wheel drive chain that is positioned on the same axis as the pedal crankshaft. A chain sprocket, and a one-way clutch for manpower driving that has an inner portion and an outer portion through which the pedal crankshaft passes and is interposed in a manpower driving system between the pedal crankshaft and the chain sprocket. In the electric bicycle drive device for transmitting both the manpower applied to the pedal and the power of the motor to the rear wheel drive chain, an inner portion of the one-way clutch is connected to the chain sprocket, and the one-way clutch The outer part of the cylinder is opposed to the inner part, and the inner part in the radial direction from one end of the cylinder in the axial direction. A crank rotation input shaft that extends from the outer portion to the opposite side of the chain sprocket and is coupled to the pedal crankshaft at the end in the extending direction. Are coupled by a spline, the power of the motor is controlled to a magnitude corresponding to the magnitude of the human power, and a sensor for detecting the magnitude of the human power includes a detected portion provided on the crank rotation input shaft, The magnetostrictive torque sensor includes a detection coil surrounding the detected portion.

An electric bicycle drive device according to an invention described in claim 2 is the electric bicycle drive device according to claim 1, wherein a detected portion of a rotation detection sensor is provided on an outer portion of the one-way clutch. is there.

According to this invention, the output member of a one-way clutch is comprised by the said inner part. This inner part can be formed in a cylindrical shape in which the difference in outer diameter between the part facing the outer part and the part supporting the chain sprocket is small.
For this reason, since this inner part does not form a step in the outer peripheral part as compared with the case where the outer part is used as an output member, or even if formed, it becomes small, so even when it is formed by forging or sintering It can be manufactured easily. In particular, since the outer diameter of the inner portion can be made relatively small over the entire region in the axial direction, when the inner portion is formed by sintering, the load applied during molding press can be reduced.

  Further, the inner part can be formed of an inexpensive material having a lower strength than the outer part. In addition, even when machining is performed to form the bearing fitting portion on the outer peripheral portion of the inner portion, the machining allowance is small, so that waste of material can be saved.

On the other hand, the outer part eliminates the need for a cylindrical part to support the chain sprocket as compared to the outer part of a conventional one-way clutch, so that the amount of expensive high-strength material used can be reduced and a bearing is fitted on the outer periphery. Since there is no need to combine them, useless materials that are deleted by machining can be minimized.
Therefore, according to the present invention, the manufacturing cost of the one-way clutch of the human power drive system can be kept low, so that the electric bicycle drive device can be provided at low cost.

Moreover, according to this invention , an outer part can be shape | molded in the shape close | similar to a final shape by forging or sintering. For this reason, it is not necessary to machine the outer portion or even if machining is performed, the amount of machining can be reduced, so that the manufacturing cost of the one-way clutch can be further reduced.
Furthermore, according to the present invention, the magnetostrictive torque sensor can be provided at a position adjacent to the one-way clutch for driving manpower in the axial direction. For this reason, according to the present invention, the electrically assisted electric bicycle drive device in which the output of the motor increases or decreases in accordance with the magnitude of human power can be formed so as not to increase in size in the radial direction. .

According to the invention described in claim 2 , the outer portion of the one-way clutch rotates integrally with the pedal crankshaft, and the chain sprocket continues to rotate by stopping the rotation of the pedal crankshaft. Stop even if there is. Therefore, according to the present invention, the rotation speed and rotation of the pedal crankshaft are provided by the rotation detection sensor having a simple structure provided on the housing side of the drive device by providing the rotation detection teeth and the permanent magnet in the outer portion. The direction can be detected accurately.

  Therefore, according to the present invention, for example, when the occupant stops the pedal, the driving by the motor is stopped, and the operation / stop of the motor can be switched in accordance with the intention of the occupant. In the conventional electric bicycle drive device, the outer part of the one-way clutch of the human-powered drive system cannot be reversed together with the pedal crankshaft, and can rotate integrally with the chain sprocket even if the pedal crankshaft stops. is there. For this reason, in the conventional drive device, even if the rotation of the outer portion is detected, the rotation of the pedal crankshaft cannot be accurately detected, and as a result, the rotation speed and direction of the pedal crankshaft are detected. Had to use an expensive sensor with a special structure.

  According to the invention described in claim 4, the magnetostrictive torque sensor can be provided at a position adjacent to the one-way clutch for driving manpower in the axial direction. For this reason, according to the present invention, the electrically assisted electric bicycle drive device in which the output of the motor increases or decreases in accordance with the magnitude of human power can be formed so as not to increase in size in the radial direction. .

Hereinafter, an embodiment of an electric bicycle driving apparatus according to the present invention will be described in detail with reference to FIGS.
An electric bicycle 1 shown in FIG. 1 includes a driving device 4 in a hanger portion 3 of a vehicle body frame 2, and power is transmitted from the driving device 4 to a rear wheel driving chain 5 and a rear wheel 6 free wheel (not shown). The vehicle travels by being transmitted to the rear wheel 6 via The driving device 4 may switch between a mode of traveling by human power only (human power driving mode) and a mode of driving by the combined force of human power and motor 7 (see FIG. 3) (electric assist mode). It is configured to be able to. A battery 9 for supplying power to the motor 7 is detachably mounted between the seat tube 8 and the rear wheel 6 of the body frame 2.

  As shown in FIGS. 1 and 2, the driving device 4 is fixed to the vehicle body frame 2 via a bracket 2a. As shown in FIG. 3, the drive device 4 includes a drive device housing 11 formed so as to be divided in the vehicle width direction, a motor 7 attached to the rear side of the drive device housing 11 and on the left side of the vehicle body, The pedal crankshaft 12, the one-way clutch 13, the chain sprocket 14, the magnetostrictive torque sensor 15, and the motor drive system provided at the rear of the drive device housing 11 are provided at the front portion of the drive device housing 11. A motor output shaft 16 and the like are provided.

  The drive device housing 11 is formed so as to be divided into a left half of the vehicle body (hereinafter simply referred to as the left housing 21) and a right half of the vehicle body (hereinafter simply referred to as the right housing 22). The left housing 21 and the right housing 22 are coupled to each other by coupling bolts 23 (see FIGS. 2 and 3). The drive device housing 11 is attached to the bracket 2a by three fixing bolts 24 as shown in FIG.

  The motor 7 is a brushless DC motor, and includes a stator 26 fixed inside the motor housing 25 and a rotor 27 provided inside the stator 26 as shown in FIG. The rotor 27 is rotatably supported by bearings 28 and 29 on the motor housing 25 and the left housing 21 in a state where the axis is parallel to the vehicle width direction.

  The rotation shaft 31 of the rotor 27 passes through the left housing 21 and is inserted into the drive device housing 11. The tip end of the rotating shaft 31 forms a gear and meshes with the driven gear 32. The driven gear 32 is supported on a motor output shaft 16 adjacent to the rotary shaft 31 via a one-way clutch 33 of a motor drive system. The one-way clutch 33 is configured such that power is transmitted only from the rotary shaft 31 to the motor output shaft 16.

The gear comprising the rotating shaft 31 and the driven gear 32 constitute a gear reducer so that the rotation of the rotating shaft 31 is decelerated and transmitted to the motor output shaft 16.
The motor output shaft 16 is positioned on the rear side of the vehicle body from the rotary shaft 31 so as to be parallel to the rotary shaft 31. The left end portion of the motor output shaft 16 on the vehicle body is rotatably supported by the left housing 21 by a bearing 34, and the right end portion of the motor output shaft 16 on the vehicle body is rotatably supported by the right housing 22 by a bearing 35. ing.

  Further, the end portion of the motor output shaft 16 on the right side of the vehicle body is formed so as to penetrate the right housing 22 and protrude from the drive device 4 to the right side of the vehicle body. As shown in FIG. 2, a motor drive sprocket 36 is attached to the projecting portion in order to transmit the power of the motor 7 to the rear wheel drive chain 5. That is, the power of the motor 7 is transmitted from the rotating shaft 31 to the rear wheel drive chain 5 via the driven gear 32, the one-way clutch 33 of the motor drive system, the motor output shaft 16, and the motor drive sprocket 36. The chain 5 passes through the upper side of the motor drive sprocket 36, and is pushed downward by a chain tensioner 37 located near the lower portion of the sprocket 36, so that the winding angle of the sprocket 36 is set to a predetermined angle. It is wrapped to become.

  As shown in FIGS. 3 and 4, the pedal crankshaft 12 provided at the front portion of the drive device housing 11 is formed to have a length penetrating the drive device housing 11 in the vehicle width direction, and its axis is The drive device housing 11 is mounted in a state parallel to the vehicle width direction. As shown in FIGS. 1 and 3, cranks 12b having pedals 12a are attached to both ends of the pedal crankshaft 12, respectively.

An end of the pedal crankshaft 12 on the left side of the vehicle body is rotatably supported by a bearing 41 on the left housing 21.
An end portion of the pedal crankshaft 12 on the right side of the vehicle body is rotatably supported by a bearing metal 42 on an inner peripheral portion of a one-way clutch 13 for driving manpower described later. The one-way clutch 13 is of a ratchet type, and is formed in a cylindrical shape extending in the vehicle width direction, and an inner portion 43 through which the pedal crankshaft 12 passes, and a claw member 44 on the outer peripheral portion of the inner portion 43. It is comprised by the outer part 45 connected via.

  As shown in FIG. 4, the inner portion 43 includes a claw holding portion 46 positioned at the left end of the vehicle body so as to face an outer portion 45 described later, and a crank extending from the claw holding portion 46 to the right side of the vehicle body. The rotation output shaft 47 is comprised. The claw holding portion 46 is pivoted so as to rotate the claw member 44 integrally by a plurality of arc-shaped concave portions formed in the circumferential direction.

  The crank rotation output shaft 47 is formed so as to penetrate the right housing 22 and protrude from the right housing 22 to the right side of the vehicle body, and is rotatably supported by the right housing 22 by a bearing 48. That is, the right end of the pedal crankshaft 12 on the vehicle body is rotatably supported by the right housing 22 via the bearing metal 42, the inner portion 43, and the bearing 48.

  A spline 49 is formed at an end of the crank rotation output shaft 47 on the right side of the vehicle body, and the chain sprocket 14 is attached in a state of being fitted to the spline 49. As shown in FIG. 2, the chain sprocket 14 is wound around the rear wheel drive chain 5.

The claw member 44 of the one-way clutch 13 is held by a claw holding portion 46 of the inner portion 43 so as to be tiltable with respect to the inner portion 43, and is urged in a standing direction by a spring 44a. The tip of the claw member 44 is engaged with teeth 50 (see FIG. 4) formed on the inner peripheral portion (outer engagement portion) of the outer portion 45.
The claw member 44 and the teeth 50 of the outer portion 45 are such that power is transmitted from the outer portion 45 to the inner portion 43 via the claw member 44 only when the outer portion 45 rotates in the same direction as the pedal crankshaft 12. It is formed so that.
The outer portion 45 includes the cylinder 51 having the teeth 50 and facing the inner portion 43, and an inner flange extending radially inward from one axial end portion (the left end portion of the vehicle body) of the cylindrical portion 51. 52.

  The outer portion 45 is applied with a force in a direction extending outward in the radial direction by the claw member 44, and needs to be formed so as to have higher strength than the inner portion 43. The outer portion 45 according to this embodiment is formed into a predetermined shape by forging or sintering using a material having a relatively high strength so that the strength is higher than that of the inner portion 43. The inner portion 43 can also be formed by forging or sintering.

  A detected portion 54 that is detected by a rotation detection sensor 53 attached to the driving device housing 11 can be provided on the outer peripheral portion of the outer portion 45. Examples of the detected portion 54 include rotation detection teeth formed on the outer peripheral portion of the outer portion 45 and permanent magnets fixed to the outer peripheral portion of the outer portion 45. The rotation detection sensor 53 can be attached to a portion of the drive device housing 11 that faces the outer peripheral surface of the cylinder 51 or the inner flange 52.

The inner flange 52 is formed in an annular shape as viewed from the axial direction so as to extend radially inward from the entire circumferential direction of the cylinder 51.
A crank rotation input shaft 55 to be described later is coupled to the inner peripheral portion of the inner flange 52 so as to rotate integrally.

  As shown in FIGS. 3 and 4, the crank rotation input shaft 55 is formed in a cylindrical shape and is supported by the pedal crankshaft 12 in a state in which the pedal crankshaft 12 penetrates. More specifically, a spline 57 that is fitted to a spline 56 formed on the outer peripheral portion of the pedal crankshaft 12 is formed at the end of the crank rotation input shaft 55 on the left side of the vehicle body, and is integrated with the pedal crankshaft 12. Combined to rotate. On the other hand, a spline 59 that fits to a spline 58 formed on the inner peripheral portion of the inner flange 52 is formed at the right end of the crank rotation input shaft 55 in the vehicle body so that it rotates integrally with the inner flange 52. Is bound to.

Further, the inner peripheral portion of the crank rotation input shaft 55 is rotatably supported on the pedal crankshaft 12 by a bearing metal 60.
That is, the rotation of the pedal crankshaft 12 is transmitted from the crank rotation input shaft 55 to the chain sprocket 14 through the outer portion 45, the claw member 44, and the inner portion 43 of the one-way clutch 13.

As shown in FIG. 4, a large number of inclined grooves 61 constituting a detected portion of the magnetostrictive torque sensor 15 are provided on the outer peripheral portion of the crank rotation input shaft 55.
The magnetostrictive torque sensor 15 has the same structure as that used in a conventional electrically assisted bicycle, detects a change in magnetic permeability that occurs when the crank rotation input shaft 55 transmits torque, and displays it as a detection signal. It is configured to send to a control device not shown.

That is, the torque sensor 15 includes a spiral inclined groove 61 formed on the outer peripheral surface of a portion between the connection point of the crank rotation input shaft 55 and the pedal crankshaft 12 and the connection point of the outer portion 45. , 61..., And an excitation coil and a detection coil provided so as to cover the periphery of the inclined groove 61. In FIG. 4, the excitation coil and the detection coil are depicted as one coil 62. A large number of the inclined grooves 61 are arranged in the circumferential direction of the pedal crankshaft 12, and the inclined groove groups are formed in parallel in the axial direction of the pedal crankshaft 12. In addition, the inclined grooves 61 of these two inclined groove groups are formed so that the inclination direction is symmetric with respect to the axis.
The excitation coil and the detection coil are wound around a coil bobbin 63 and supported by the left housing 21 via a holding member 64 having the coil bobbin 63.

  When the control device is in an assist mode in which the power of the motor 7 is used as auxiliary power, the rotational torque of the pedal crankshaft 12, that is, the magnitude of human power is obtained by calculation based on the detection data of the torque sensor 15, The output of the motor 7 is controlled so that an assist force having a magnitude proportional to the magnitude of the human power is generated.

  The electric bicycle 1 having the drive device 4 configured as described above travels when the occupant depresses the pedal 12a in the manual driving mode. At this time, the pedaling force applied to the pedal 12a moves from the pedal crankshaft 12 to the crank rotation input shaft 55, the outer portion 45 of the one-way clutch 13, the claw member 44, the inner portion 43, the chain sprocket 14 and the rear wheel drive chain 5. To the rear wheel 6.

  On the other hand, in the electric bicycle 1, in the assist mode in which the power of the motor 7 is used as auxiliary power, the magnitude of the human force applied to the pedal crankshaft 12 is used as the change in the magnetic permeability of the crank rotation input shaft 55 and the magnetostrictive torque sensor. 15, and the power of the motor 7 having a magnitude corresponding to the magnitude of human power is applied from the motor output shaft 16 to the rear wheel drive chain 5. In this case, the rear wheel 6 is driven by the resultant force of the human force applied to the rear wheel drive chain 5 from the chain sprocket 14 and the power of the motor 7 applied to the rear wheel drive chain 5 from the motor output shaft 16. .

  In the driving device 4, even if the pedal crankshaft 12 is rotated in the reverse direction or the chain sprocket 14 is rotated in the forward direction faster than the pedal crankshaft 12, the one-way clutch 13 for driving manpower is used. Since the outer portion 45 of the outer sleeve 45 is disengaged from the claw member 44 and the power transmission is interrupted in the one-way clutch 13, the motor 7 is not rotated in the reverse direction, and the driving force is not transmitted to the pedal 12a from the chain 5 side.

The one-way clutch 13 for driving human power provided in the driving device 4 is configured such that human power is input from the outer portion 45 and output from the inner portion 43. That is, in the one-way clutch 13, an output member is constituted by the inner portion 43. The inner portion 43 is formed in a cylindrical shape in which a difference in outer diameter between a portion facing the outer portion 45 (claw holding portion 46) and a portion supporting the chain sprocket 14 (crank rotation output shaft 47) is small. Yes.
For this reason, since this inner part 43 is smaller than the case where the outer part 45 is formed as an output member of the one-way clutch, no step is formed on the outer peripheral part, or even if a step is formed, Even when formed by forging or sintering, it can be easily produced.

  In this embodiment, the inner portion 43 may be formed to a thickness that can hold the claw member 44 and to which the chain sprocket 14 can be attached. Therefore, the outer diameter of the inner portion 43 is relatively small over the entire area in the axial direction. Can be formed. For this reason, when shape | molding the inner part 43 by sintering, the load added at the time of a shaping | molding press can be reduced.

  In addition, the inner portion 43 can be formed of an inexpensive material having a lower strength than the outer portion 45. In addition, even when machining is performed to form a cylindrical surface (bearing fitting surface) on which the bearing 48 is fitted on the outer peripheral portion of the inner portion 43, the outer peripheral portion of the inner portion 43 is formed as described above. Since there are no steps and the processing cost is small, it is possible to eliminate waste of materials.

On the other hand, the outer portion 45 does not require a cylindrical portion for supporting the chain sprocket as compared with the outer portion of the conventional one-way clutch. For this reason, in this embodiment, the amount of expensive high-strength material used can be reduced. Furthermore, the outer portion 45 according to this embodiment does not require a bearing to be fitted to the outer peripheral portion. For this reason, according to this Example, the useless material deleted by the machining from the outer part 45 can be minimized.
Therefore, according to this embodiment, since the manufacturing cost of the one-way clutch 13 for driving human power can be kept low, the electric bicycle driving device 4 can be manufactured at low cost.

  Further, according to this embodiment, since the outer portion 45 is constituted by the cylinder 51 and the inner flange 52, the outer portion 45 can be easily formed by forging or sintering because there is no step and the shape is simple. it can. For this reason, even if the outer portion 45 is subjected to machining such as cutting or grinding, the amount of processing can be reduced, and therefore the manufacturing cost of the one-way clutch 13 can be further reduced.

  According to this embodiment, the outer portion 45 of the one-way clutch 13 for driving manpower is always rotated integrally with the pedal crankshaft 12. Further, the outer portion 45 stops even when the chain sprocket 14 continues to rotate by stopping the rotation of the pedal crankshaft 12. For this reason, according to this embodiment, the outer portion 45 is provided with rotation detection teeth, or the outer portion 45 is provided with a permanent magnet (detected portion 54). The rotation speed and direction of the pedal crankshaft 12 can be accurately detected by the structure rotation detection sensor 53.

  Therefore, according to this embodiment, for example, when the occupant stops the operation of depressing the pedal 12a, the motor 7 is stopped immediately, so that the operation / stop of the motor 7 can be switched according to the occupant's intention. become.

  In the electric bicycle drive device 4 according to this embodiment, a magnetostrictive torque sensor 15 is provided at a position adjacent to the one-way clutch 13 for driving human power in the axial direction. Therefore, according to this embodiment, the electrically assisted electric bicycle drive device 4 in which the output of the motor 7 increases or decreases in accordance with the magnitude of human power is formed so as not to increase in size in the radial direction. be able to.

In the above-described embodiment, an example in which the present invention is applied to an electrically assisted electric bicycle has been shown. However, the present invention is also applied to a self-propelled electric bicycle that travels by generating motor power independently of a human power drive system. Can be applied.
Further, the drive device 4 according to this embodiment adopts a configuration in which the power of the motor 7 is transmitted from the motor drive sprocket 36 to the rear wheel drive chain 5, but the power of the motor 7 is driven manually in the drive device 4. It is also possible to adopt a configuration for transmitting to the rotating parts of the system. In this case, the power of the motor 7 is transmitted to the inner part 43 of the one-way clutch 13 for driving manpower by a gear or the like.

1 is a side view of an electric bicycle equipped with a drive device according to the present invention. It is a side view of the drive device for electric bicycles concerning the present invention. It is the III-III sectional view taken on the line in FIG. It is sectional drawing which expands and shows a principal part.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 ... Electric bicycle, 4 ... Electric bicycle drive device, 5 ... Rear wheel drive chain, 7 ... Motor, 11 ... Drive device housing, 12 ... Pedal crankshaft, 13 ... One-way clutch, 15 ... Magnetostrictive torque sensor, 43 ... Inner part, 45 ... Outer part, 51 ... Cylinder, 52 ... Inner flange, 55 ... Crank rotation input shaft, 62 ... Coil for detection.

Claims (2)

A pedal crankshaft to which the pedal is connected;
A chain sprocket positioned on the same axis as the pedal crankshaft and wound with a rear wheel drive chain;
A one-way clutch for manpower driving, which has an inner portion and an outer portion through which the pedal crankshaft penetrates and is interposed in a manpower driving system between the pedal crankshaft and the chain sprocket, and in addition to the pedal In the electric bicycle drive device that transmits both the human power and the power of the motor to the rear wheel drive chain,
The inner part of the one-way clutch is connected to the chain sprocket, and the outer part of the one-way clutch extends radially inward from a cylinder facing the inner part and one end of the cylinder in the axial direction. Consisting of an inner flange and
A crank rotation input shaft extending from the outer portion to the opposite side of the chain sprocket and coupled to the pedal crankshaft at the end in the extending direction is coupled to the inner flange by a spline .
The power of the motor is controlled to a magnitude corresponding to the magnitude of human power,
The sensor for detecting the magnitude of human power is constituted by a magnetostrictive torque sensor having a detected portion provided on the crank rotation input shaft and a detection coil surrounding the detected portion. Electric bicycle drive device.   The electric bicycle drive device according to claim 1, wherein a detected portion of a rotation detection sensor is provided on an outer portion of the one-way clutch.

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