JP2016094049A - Drive unit and power-assisted bicycle - Google Patents

Abstract

PROBLEM TO BE SOLVED: To downsize a drive unit of a power-assisted bicycle while securing yield performance of the drive unit.SOLUTION: A drive unit 40 includes: a housing 51; a crank shaft 41; a motor 61 accommodated in the housing 51; a gear 82; a gear shaft 81; and a control board 38. The control board 38 is one out of two boards having the same shape obtained by cutting a surface of a rectangular original board. A cutting line following this cutting includes a non-parallel line which is not parallel to a side vertical to a side passed by the rectangular cutting line of the original board. A part of the control board 38 is disposed between a first shaft and a second shaft that are two shafts out of the crank shaft 41, a motor shaft 64, and the gear shaft 81. In an axial view of the first shaft, at least a part of the first shaft is included in a virtual rectangle defined by a side of the control board facing the cutting line, and a longer side out of two sides connected to the side of the control board.SELECTED DRAWING: Figure 5

Description

  The present invention relates to a drive unit used for a battery-assisted bicycle.

  There is known a battery-assisted bicycle that assists a driver's pedaling force (hereinafter referred to as a pedaling force) with a driving force of a motor. The battery-assisted bicycle includes a drive unit for assisting the pedal effort. The drive unit is disclosed in, for example, Japanese Patent Application Laid-Open No. 2007-176354.

  In the above publication, the drive unit is disposed adjacent to the crankshaft and includes a drive motor, a circuit board, a reduction gear, and the like that rotate the axle of the rear wheel. Electronic components for controlling the output of the drive motor are mounted on the circuit board.

JP 2007-176354 A

  It is preferable to reduce the size of the drive unit of the battery-assisted bicycle. Here, it is conceivable to reduce the size of the drive unit by reducing the area of the control board. However, there is a limit to reducing the area of the control board on which electronic components that control the motor are mounted. This is because it is difficult to significantly reduce the number or area of electronic components mounted on the control board. From the viewpoint of yield, the control board is preferably formed in a rectangular shape (including a square, the same applies hereinafter). If a non-rectangular substrate is to be formed, a complicated substrate cutting process, an increase in the number of parts discarded after cutting, and the like are likely to occur. As a result, production efficiency deteriorates and costs increase.

  SUMMARY OF THE INVENTION Accordingly, an object of the present invention is to reduce the size while securing the yield of a drive unit of a battery-assisted bicycle.

Means for Solving the Problems and Effects of the Invention

  The drive unit in one embodiment of the present invention is a drive unit used for a battery-assisted bicycle. The drive unit includes a housing, a crankshaft penetrating the housing, a motor housed in the housing and having a motor shaft, a gear housed in the housing and meshed with the motor shaft of the motor, and a gear provided with the gear And a control board disposed in a plane substantially perpendicular to the axial direction of the crankshaft in the housing. The control board is one of two boards having the same shape formed by cutting the surface of the rectangular original board. The cutting line by this cutting includes a non-parallel line that is not parallel to the side perpendicular to the side through which the rectangular cutting line of the original substrate passes. A part of the control board is disposed between the first shaft and the second shaft, which are two of the crank shaft, the motor shaft, and the gear shaft. As viewed in the axial direction of the first axis, at least a part of the first axis is a virtual rectangle determined by the side of the control board facing the cutting line and the longer side of the two sides connected to the side Contained within.

FIG. 1 is a right side view showing a battery-assisted bicycle according to an embodiment. FIG. 2 is a right side view of the drive unit and driven sprocket of the battery-assisted bicycle shown in FIG. 3 is a cross-sectional view of the drive unit of FIG. 2 taken along line III-III. FIG. 4 is a plan view of the first case and the motor as viewed from the mating surface side. FIG. 5 is a diagram illustrating a state in which a component group including a control board is attached to the first case illustrated in FIG. 4. FIG. 6 is a view for explaining the shape of the control board shown in FIG. FIG. 7 is a diagram illustrating an example in which four control boards are cut out from one rectangular sheet. FIG. 8 is a plan view of the second case as seen from the mating surface side with the first case. FIG. 9 is a diagram showing one of the modified examples of the shape of the control board. FIG. 10 is a diagram illustrating another modification of the shape of the control board. FIG. 11 is a diagram showing still another modified example of the shape of the control board. FIG. 12 is a diagram illustrating a modified example of the arrangement of the control board and the two axes. FIG. 13 is a diagram illustrating another modification of the arrangement of the control board and the two axes. FIG. 14 is a diagram showing still another modified example of the arrangement of the control board and the two axes.

  In order to reduce the size of the drive unit of the battery-assisted bicycle, various ideas have been made by the inventors of the present invention in the arrangement of components housed in the drive unit housing. The housing accommodates, for example, a motor, a crankshaft, a gear for transmitting the rotation of the motor to the output shaft, a control board on which electronic components for controlling the motor are mounted. In order to make these arrangements compact, it is conceivable to make the drive unit compact by devising the relative positional relationship between components such as the motor and gear in the drive unit and the crankshaft. As one method, the inventors can arrange the control board between two of the motor shaft, the gear shaft and the crank shaft of the motor so that the components can be efficiently arranged in the housing, and the drive unit can be made compact. I came up with what I can do.

  However, the control board disposed between the two axes may prevent the distance between the axes from being reduced. Here, it is difficult to significantly reduce the number or area of electronic components mounted on the control board. Therefore, there is a limit to reducing the area of the control board. In addition, it is difficult to arrange the control board surface between the two axes in a direction parallel to the axis. This is because a meshing portion such as a gear for transmitting a driving force is disposed between the shafts. Therefore, it is conceivable that the surface of the control board is formed in a non-rectangular shape and is efficiently arranged in the space in the housing without reducing the area of the control board. However, it is not preferable that the control board has a non-rectangular shape from the viewpoint of yield in the manufacturing process.

  Therefore, the inventors of the present application have found a configuration that can reduce the size of the drive unit of the battery-assisted bicycle while ensuring the yield.

  Hereinafter, a drive unit and a battery-assisted bicycle according to embodiments of the present invention will be described with reference to the drawings. In the drawings, the same or corresponding parts are denoted by the same reference numerals, and description of the members will not be repeated. Moreover, the dimension of the structural member in each figure does not faithfully represent the actual dimension of the structural member, the dimensional ratio of each structural member, or the like. In the following description, front, rear, left, and right mean front, rear, left, and right as viewed from the driver who is seated on the saddle (seat 24) and holds the handle 23. To do.

<Example of overall configuration of a battery-assisted bicycle>
FIG. 1 is a right side view showing a battery-assisted bicycle 1 according to an embodiment. FIG. 2 is a right side view showing the drive unit 40 and the driven sprocket 45 of the battery-assisted bicycle 1 according to the embodiment.

  As shown in FIG. 1, the battery-assisted bicycle 1 has a body frame 11. The body frame 11 extends in the front-rear direction. The vehicle body frame 11 includes a head pipe 12, a down frame 13, a seat frame 14, a pair of chain stays 16, and a pair of seat stays 17. The head pipe 12 is disposed at the front portion of the battery-assisted bicycle 1. The front end of the down frame 13 is connected to the head pipe 12. The down frame 13 extends in the front-rear direction. The down frame 13 extends obliquely downward. The seat frame 14 is connected to the rear end of the down frame 13. The seat frame 14 extends upward and obliquely rearward from the rear end of the down frame 13.

  As shown in FIG. 2, a bracket 15 is attached to the rear end of the down frame 13. A pair of chain stays 16 are connected to the rear end of the bracket 15. The pair of chain stays 16 are arranged so as to sandwich the rear wheel 22 from the left and right. As shown in FIG. 1, one end of a seat stay 17 is connected to the rear end of each chain stay 16. The pair of seat stays 17 are arranged so as to sandwich the rear wheel 22 from the left and right. As shown in FIG. 1, the other end of each seat stay 17 is connected to the upper portion of the seat frame 14.

  Below the bracket 15, the drive unit 40 is attached by the fastening bracket 30. The drive unit 40 has a housing 51 that forms the outer shape of the drive unit 40. A motor 61 is stored in the housing 51. A crankshaft 41 penetrates the front portion of the housing 51 in the left-right direction. The crankshaft 41 is rotatably supported with respect to the housing 51 via a plurality of bearings.

  Crank arms 31 and 32 are attached to both ends of the crankshaft 41. Pedals 33 and 34 are attached to the tips of the crank arms 31 and 32, respectively. When the user steps on the pedals 33 and 34, the crankshaft 41 rotates. A chain 46 is wound around the drive sprocket 42 and the driven sprocket 45.

  Further, the gear shaft 81 passes through the right side of the housing 51. A gear meshed with the motor shaft of the motor 61 is attached to the gear shaft 81. In this example. The gear shaft 81 is an output shaft that transmits the rotation of the motor 61 to the outside. An auxiliary sprocket 43 is connected to a portion of the gear shaft 81 that protrudes from the housing 51. The auxiliary sprocket 43 is wound around the chain 46. The teeth of the auxiliary sprocket 43 are applied to the chain 46 from the outer peripheral side of the chain 46.

  A chain tensioner 86 is disposed at the rear right side of the housing 51 and behind the gear shaft 81. A tension sprocket 90 is rotatably attached to the chain tensioner 86 by a support bolt 89. One end of the chain tensioner 86 is rotatably connected to the housing 51 by a support bolt 88. The other end of the chain tensioner 86 is connected to the housing 51 via a tension spring 87. A chain 46 is wound around the tension sprocket 90 so as to push the tension sprocket 90 backward. The teeth of the tension sprocket 90 are applied to the chain 46 from the inner peripheral side of the chain 46. The chain tensioner 86 applies an appropriate tension to the chain 46 by the elastic force of the tension spring 87.

  The drive sprocket 42 and the auxiliary sprocket 43 transmit driving force to the rear wheel 22 through the chain 46. Specifically, the pedal depression force generated when the user steps on the pedals 33 and 34 causes the driving sprocket 42 to rotate in the forward rotation direction and the driving force to rotate the rear wheel 22 in the forward rotation direction via the chain 46. As transmitted. The rotational force generated by the operation of the motor 61 is transmitted as an auxiliary driving force that rotates the auxiliary sprocket 43 in the backward rotation direction and rotates the rear wheel 22 in the forward rotation direction via the chain 46. Thereby, the pedal depression force generated by the user depressing the pedals 33 and 34 is assisted by the driving force output from the motor 61.

  A handle stem 25 is rotatably inserted into the head pipe 12. A handle 23 is fixed to the upper end of the handle stem 25. A front fork 26 is fixed to the lower end of the handle stem 25. A front wheel 21 is rotatably supported on the lower end of the front fork 26 by an axle 27.

  Grips 73 are attached to the left and right ends of the handle 23, respectively. A left brake lever 74 is attached to the left part of the handle 23, and a right brake lever 75 is attached to the right part of the handle 23. The left brake lever 74 is a lever for operating the brake (not shown) of the rear wheel 22. The right brake lever 75 is a lever for operating the brake (not shown) of the front wheel 21.

  A seat pipe 28 is inserted into the cylindrical seat frame 14. A seat 24 is provided at the upper end of the seat pipe 28.

  A rear wheel 22 is rotatably supported by an axle 29 at the rear ends of the pair of chain stays 16. A driven sprocket 45 coaxial with the axle 29 is provided on the right side of the rear wheel 22. The driven sprocket 45 is connected to the rear wheel 22 via a one-way clutch (not shown).

  A chain cover 47 is attached to the body frame 11. The chain cover 47 has a main cover 48 and a sub cover 49. The main cover 48 extends in the front-rear direction. The main cover 48 covers the right front portion of the drive unit 40 and the chain 46. The sub cover 49 covers the right rear portion of the drive unit 40.

  A battery unit 35 is disposed behind the seat frame 14. The battery unit 35 supplies power to the motor 61 of the drive unit 40. The battery unit 35 includes a battery and a battery control unit (not shown). The battery is a chargeable / dischargeable rechargeable battery. The battery control unit controls the charging / discharging of the battery, and monitors the output current and remaining capacity of the battery. An electric wire for supplying electric power from the battery to the motor 61 is provided between the battery unit 35 and the drive unit 40.

<Configuration example of drive unit>
FIG. 3 is a cross-sectional view of the drive unit 40 of FIG. 2 taken along line III-III. As shown in FIG. 3, the drive unit 40 includes a housing 51, a crankshaft 41, a drive force generator 60, and a chain tensioner 86. The driving force generator 60 includes a motor 61 having a motor shaft 64 (rotating shaft), and a gear 82 and a gear shaft 81 that transmit the rotation of the motor shaft 64 to the outside of the driving unit 40.

[housing]
The housing 51 has a first case 53 and a second case 52. The first case 53 and the second case 52 are combined with each other from the left and right, and are fixed to each other by a plurality of fasteners 54. The first case 53 and the second case 52 are each made of a metal material. The metal material is, for example, an aluminum alloy. The housing 51 is attached to the bracket 15 by the fastening fitting 30 (see FIG. 2).

  The first case 53 and the second case 52 are in contact with each other on a mating surface perpendicular to the axial direction of the motor shaft 64 (the rotation shaft of the motor 61). In this example, the crankshaft 41 and the gear shaft 81 are parallel to the motor shaft 64, and the mating surface of the first case 53 and the second case 52 is a surface that is also perpendicular to the crankshaft 41 and the gear shaft 81. It has become.

As shown in FIG. 3, the first case 53 includes a first housing portion 53 </ b> R that configures the right portion of the drive unit 40 and a second housing portion 53 </ b> L that configures the left portion of the drive unit 40 in the in-vehicle state. The first housing portion 53R is formed larger than the second housing portion 53L. The first housing portion 53R and the second housing portion 53L are divided by a motor shaft support wall 53E. The second case 52 is fixed to the first case 53 so as to close the first housing portion 53R of the first case 53. The first housing portion 53R houses the gear shaft 81, the gear 82, the control board 38, the crank shaft 41, and the like. The stator 62 and the rotor 63 of the motor 61 are housed in the second housing portion 53L.
[motor]

  The motor 61 generates an auxiliary driving force for assisting the traveling of the battery-assisted bicycle 1 by the pedal depression force based on a control signal output from the control board 38.

  The motor 61 has a stator 62, a rotor 63 and a motor shaft 64. The rotor 63 is fixed to the motor shaft 64. Thereby, the rotor 63 is rotatably attached together with the motor shaft 64. That is, the rotor 63 rotates integrally with the motor shaft 64. The rotor 63 is a permanent magnet in which N poles and S poles are alternately magnetized in the circumferential direction.

  The stator 62 is disposed outside the rotor 63 in the radial direction of the rotor 63. The stator 62 includes a plurality of bobbins 62B around which coils 62A are wound. The plurality of bobbins 62 </ b> B are arranged side by side in the circumferential direction of the rotor 63. An iron core 62C is inserted into each bobbin 62B. A surface of the stator 62 opposite to the rotor 63, that is, a radially outer surface is supported by the stator support wall 53 b of the first case 53. That is, the radially outer side of the motor 61 is supported by the first case 53. The stator support wall 53 b extends in the axial direction of the motor shaft 64 and is provided on the outer periphery of the stator 62 so as to include the motor 61 when viewed from the axial direction of the motor shaft 64. The outer peripheral portion of the stator 62 is fixed to the first case 53 of the housing 51.

  The first case 53 includes a motor shaft support wall 53E that is a partition that separates the first housing portion 53R and the second housing portion 53L. The motor shaft support wall 53 </ b> E supports the motor shaft 64 inside the housing 51. The motor shaft support wall 53E includes a surface perpendicular to the axial direction of the motor shaft, and is connected to the stator support wall 53b. The stator support wall 53b is provided on the opposite side of the second case 52 (the mating surface 53A) across the motor shaft support wall 53E. That is, the stator support wall 53b is formed to extend from the radially outer side of the motor shaft support wall 53E to the opposite side to the second case 52.

  The motor shaft support wall 53E is provided with a shaft hole 53G through which the motor shaft 64 passes. A gear groove 64a is formed on the outer periphery of the portion of the motor shaft 64 protruding from the shaft hole 53G toward the second case 52 from the end of the motor shaft 64 to the center. The rotor 63 is fixed to a portion of the motor shaft 64 that extends from the shaft hole 53G to the opposite side of the second case 52.

  A motor cover 65 is attached to the first case 53 so as to cover an area where the rotor 63 and the stator 62 are disposed. The motor cover 65 is fixed to the first case 53 by a plurality of fasteners 76. The motor cover 65 is provided on the opposite side to the second case 52 with respect to the first case 53. The mating surface of the first case 53 and the motor cover 65 is a surface perpendicular to the motor shaft 64. The motor cover 65 is in contact with the stator support wall 53 b of the first case 53.

  The end of the motor shaft 64 opposite to the end provided with the gear groove 64 a is rotatably supported by the motor cover 65 via a rolling bearing 67. The central portion of the motor shaft 64 is supported by the first case 53 via a rolling bearing 66 provided around the shaft hole 53G of the first case 53. Thus, the motor 61 is supported by the motor shaft support wall 53E, the stator support wall 53b, and the motor cover 65.

[gear]
The gear shaft 81 is disposed on the opposite side of the crank shaft 41 with respect to the motor shaft 64. The gear shaft 81 is rotatably supported with respect to the first case 53 and the second case 52 by a rolling bearing 84 disposed in the first case 53 and a rolling bearing 83 disposed in the second case 52. . The gear shaft 81 is made of a metal material. The metal material is, for example, iron.

  A gear 82 is attached to the gear shaft 81 via a one-way clutch 85. The gear 82 is disposed coaxially with the gear shaft 81 between the rolling bearing 83 and the rolling bearing 84. The gear 82 meshes with a gear groove 64 a formed on the motor shaft 64 of the motor 61. A gear reducer is configured by the gear groove 64 a and the gear 82 formed in the motor shaft 64. In the present embodiment, when the motor 61 operates, the motor shaft 64 rotates in the forward rotation direction. For this reason, the gear 82 rotates in the backward rotation direction by the rotation of the motor shaft 64 in the forward rotation direction.

  The one-way clutch 85 is configured to transmit only the rotation in the backward rotation direction generated in the gear 82 or the gear shaft 81. For this reason, when the motor 61 operates and the gear 82 rotates in the backward direction, the rotation is transmitted to the gear shaft 81 and the gear shaft 81 rotates in the backward direction. On the other hand, even if the forward rotation of the gear shaft 81 occurs, the forward rotation of the gear 82 is not transmitted.

  The second case 52 has a shaft hole through which the gear shaft 81 passes. An auxiliary sprocket 43 is connected to the outer end of the second case 52 of the gear shaft 81. The auxiliary sprocket 43 and the gear shaft 81 are connected by, for example, a spline structure. Thereby, the rotation of the motor shaft 64 of the motor 61 is transmitted to the auxiliary sprocket 43 via the gear 82, the one-way clutch 85, and the gear shaft 81. That is, the auxiliary driving force generated by the driving force generator 60 is transmitted from the gear shaft 81 to the auxiliary sprocket 43, and the auxiliary sprocket 43 rotates in the backward rotation direction.

[Control board]
In the housing 51, the control board 38 is fixed to the first case 53 by the fastening bracket 39. In the present embodiment, a resin cover 59 that covers at least a part of the gear 82 and the motor 61 is fixed to the first case 53. The control board 38 is fixed to the resin cover 59 by a fastener that passes through the control board 38 and the resin cover 59 and reaches the first case 53.

  The housing 51 is disposed in a plane substantially perpendicular to the axial direction of the crankshaft 41. That is, the control board 38 is formed in a plate shape, and is arranged so that the surface of the control board 38 is substantially parallel to a plane perpendicular to the axial direction of the crankshaft 41. Thereby, compared with the case where the control board 38 is arrange | positioned in the plane parallel to the axial direction of the crankshaft 41, the space in a housing can be utilized efficiently. As a result, the housing 51 can be made compact.

  Here, the control board 38 does not need to be disposed in a plane strictly perpendicular to the axial direction of the crankshaft 41. The entire surface of the control board 38 may be along a plane perpendicular to the axial direction of the crankshaft 41. For example, when a part of the control board 38 includes a portion that is not parallel to the plane perpendicular to the axial direction of the crankshaft 41, or the control board 38 as a whole is a plane perpendicular to the axial direction of the crankshaft 41. Even if it is arranged with a slight angle, it can be regarded as equivalent to that arranged in a plane perpendicular to the axial direction of the crankshaft 41.

  Electronic components that control the operation of the motor are mounted on the control board 38. The electronic component controls electric power supplied to the motor based on data detected by various sensors and data indicating an operation by the user. Therefore, the control board 38 and the motor 61 are connected to each other by an electric wire (not shown). An electric wire for supplying power from the battery unit 35 is also connected to the control board 38. Furthermore, electric wires for transmitting signals from various sensors are also connected to the control board 38. Examples of the various sensors include a rotation detection sensor that detects rotation of the crankshaft and a torque sensor that detects torque.

[Crankshaft]
The crankshaft 41 passes through the front portion of the housing 51 in a direction parallel to the motor shaft 64. The crankshaft 41 is rotatably supported by the first case 53 and the second case 52 via bearings. A rotating member 56, a one-way clutch 55, and a drive sprocket 42 are disposed on the crankshaft 41 coaxially with the crankshaft 41.

  The rotating member 56 is disposed around the crankshaft 41 in the housing 51. The rotating member 56 is substantially cylindrical. The end of the rotating member 56 on the second case 52 side is supported by the crankshaft 41 via a cylindrical slide bearing 71. The end of the rotating member 56 on the first case 53 side is connected to the crankshaft 41. The end of the rotating member 56 on the first case 53 side and the crankshaft 41 are connected by, for example, a spline structure. Thereby, the rotating member 56 rotates integrally with the crankshaft 41.

  The one-way clutch 55 is disposed around the crankshaft 41 on the second case 52 side of the rotating member 56 in the housing 51. The one-way clutch 55 includes an inner member 55a and an outer member 55b.

  The inner member 55 a is formed extending along the periphery of the crankshaft 41 from the space between the rotating member 56 in the housing 51 and the second case 52 toward the outside of the second case 52. The inner member 55a has a substantially cylindrical shape and is rotatable with respect to the crankshaft 41. A drive sprocket 42 is fixed to the outer peripheral surface of the portion of the inner member 55a that protrudes outside the housing 51. The inner member 55a and the drive sprocket 42 rotate together.

  The outer member 55b is disposed along the periphery of the crankshaft 41 so as to cover the end of the rotating member 56 and the end of the inner member 55a. The outer member 55b is substantially cylindrical. The outer member 55b and the rotation member 56 are connected by, for example, a spline structure. Thereby, the outer member 55b and the rotation member 56 rotate integrally.

  The outer member 55b and the inner member 55a are forwardly rotated from the outer member 55b to the inner member 55a (referred to as a clockwise direction when the battery-assisted bicycle 1 is viewed from the right side as shown in FIG. 1, the same applies hereinafter). It is connected to transmit only the rotational force. The outer member 55b and the inner member 55a are connected by, for example, a ratchet structure. The rotational force in the backward rotation direction (referred to as a counterclockwise direction when the battery-assisted bicycle 1 is viewed from the right side as shown in FIG. 1; hereinafter the same) is not transmitted from the outer member 55b to the inner member 55a.

  The drive unit 40 is provided with a torque detector 57 near the outer periphery of the rotating member 56. The torque detector 57 detects the torque generated in the crankshaft 41 by the pedal effort. The torque detector 57 is, for example, a magnetostrictive torque sensor, but is not limited to this. For example, the torque detector 57 may be configured to detect the torque of the crankshaft 41 from the tension generated in the chain 46 without directly detecting the torque of the crankshaft 41. The torque detection unit 57 outputs a signal corresponding to the detected torque to the control board 38.

  On the outer peripheral surface of the outer member 55b, a magnet 58a, which is a detected element in the crank rotation detection unit, is disposed. The magnet 58a can have a cylindrical shape surrounding the outer periphery of the outer member 55b. As the outer member 55b rotates, the magnetic field generated by the magnet 58a changes. By detecting the change in the magnetic field, the rotation of the crankshaft 41 can be detected.

<Detailed configuration example of the drive unit>
[Configuration example of the first case]
FIG. 4 is a plan view of the first case 53 and the motor 61 fixed to the first case 53 as seen from the mating surface side. In FIG. 4, a portion where the first case 53 and the second case 52 are in contact, that is, a mating surface 53 </ b> A of the first case 53 with the second case 52 is indicated by hatching. Further, the position of the radially inner side 62u and the position of the radially outer side 62s of the stator 62 are indicated by broken lines. Further, the position where the control board 38 is arranged is indicated by a two-dot chain line.

  As shown in FIG. 4, the first case 53 has a cylindrical shape for fixing the shaft hole 53 </ b> P through which the crankshaft 41 passes, the shaft hole 53 </ b> G through which the motor shaft 64 passes, and the end of the gear shaft 81. A body 53Q is provided.

  A motor shaft support wall 53E having a surface parallel to the mating surface 53A is disposed around the shaft hole 53G through which the motor shaft 64 passes. When viewed from the axial direction of the motor shaft 64, the motor shaft support wall 53 </ b> E extends radially from the shaft hole 53 </ b> G and reaches the outer edge of the radially outer side 62 s of the stator 62.

  In the motor shaft support wall 53E, a plurality of holes 53F are provided in the outer peripheral portion of the motor shaft 64 side by side in the drive circumferential direction of the motor 61. Terminals 69 a to 69 d and a support member 68 that supports the terminals 69 a to 69 d on the stator 62 are provided at positions corresponding to these holes 53 </ b> F of the motor 61. Terminals 69 a to 69 c are electrically connected to coil 62 </ b> A of motor 61. Further, the terminal 69d is connected to a sensor provided in the motor 61 such as the number of rotations of the motor 61, for example. Wires connecting the control board 38 and the motor 61 are connected to these terminals 69a to 69c. Electric wires 77a, 77b, 77c (see FIG. 5) connecting the motor 61 and the control board 38 pass through the hole 53F.

  A rib 53D extending in the radial direction of the motor shaft 64 is formed between two adjacent holes 53F among the plurality of holes 53F. Further, a circular rib 53K having the motor shaft 64 as the center is formed so as to intersect with the rib 53D. Furthermore, a rib 53S is formed that extends radially outward from the rib 53K and reaches the wall of the mating surface 53A of the first case 53. The ribs 53D, 53K, and 53S can increase the strength of supporting the motor 61 of the first case 53.

  A rib 53M extending in the radial direction of the gear shaft 81 from the cylindrical body 53Q and a circular rib 53N centering on the gear shaft 81 intersecting the rib 53M are formed. Further, a rib 53T is formed that extends radially outward from the rib 53N and reaches the wall of the mating surface 53A of the first case 53. These ribs 53M, 53N, and 53T can increase the strength of supporting the gear shaft 81 of the first case 53. The ribs 53D, 53K, 53S, 53M, 53N, and 53T in the first case 53 are portions where the thickness in the axial direction of the motor shaft 64 of the first case is larger than the surroundings. A part of the rib 53T and the rib 53S is provided with holes 53r1, 53r2, and 53r3 into which fasteners for fixing the control board 38 to the first case are inserted.

  The mating surface 53A is formed along the outer shape of the drive unit 40 in a cross section perpendicular to the motor shaft 64. In the surface of the mating surface 53A, a plurality of holes 53h1 to 53h8 into which fasteners for fastening the first case 53 and the second case 52 are inserted, and fasteners for fixing the drive unit 40 to the bracket 15 are provided. A plurality of through holes 53j1 to 53j3 are provided. The holes 53h1 to 53h8 can be through holes or holes that do not penetrate. The fastening metal holes 53h1 to 53h8 for fastening the first case 53 and the second case 52 and the fastening metal holes 53r1 to 53r3 for fixing the control board 38 to the first case 53 are all dug in the same direction. Yes. That is, the fastening direction of the control board 38 and the fastening direction of the first case 53 and the second case 52 are the same. Thereby, the protection strength of the control board 38 can be increased. In addition, the manufacturing process can be simplified.

  The first case 53 has a concave portion (53V) that is recessed in the axial direction of the crankshaft 41 in a region sandwiched between the mating surfaces 53A in a part of the outer shape of the drive unit 40 on a plane parallel to the mating surfaces 53A. The recess (53 </ b> V) serves as a lead-in port 53 </ b> V through which an electric wire for supplying electric power to the motor 61 from the outside of the housing 51 is drawn into the housing 51.

[Control board layout example]
FIG. 5 is a diagram illustrating a state in which a component group including the control board 38 is attached to the first case 53 illustrated in FIG. 4. The arrows between “up and down” in FIG. 5 and the arrows between “front and rear” intersecting with this indicate the up and down directions when the drive unit 40 is mounted on the battery-assisted bicycle 1, respectively. In FIG. 5, the positions of the motor shaft 64, the radially inner 62u and the radially outer 62s of the stator 62, and the radially outer 82S of the gear 82 are indicated by broken lines.

  In FIG. 5, a gear shaft 81, a gear 82, and a crankshaft 41 are attached to the first case 53. A resin cover 59 is placed so as to cover a part of the gear 82 and the motor shaft 64. The control board 38 is attached to the resin cover 59. In a vehicle-mounted state, control is performed so that one surface of the control board 38 faces the right side (front side in FIG. 5) and the other surface opposite to the one surface faces the left side (back of the paper surface in FIG. 5). A substrate 38A is attached. On one surface and the other surface of the control board 38, electronic components 38A and terminals to which electric wires are connected are arranged. Examples of the electronic component 38A that can be mounted on the control board 38 include a power semiconductor element (power device), a capacitor, an IC, and a sensor.

  The control board 38 and the motor 61 are connected to each other by electric wires 77a, 77b, 77c and the like. Specifically, terminals 72a, 72b, and 72c (hereinafter referred to as distinctions) of the other ends of the electric wires 77a, 77b, and 77c (hereinafter referred to as electric wires 77) that are connected to the control board 38 at one end. If not, the terminal 72 is connected to the terminals 69a, 69b, and 69c (see FIG. 4) of the motor 61, respectively.

  The electric wire 77 is a conducting wire that supplies electric power to the motor 61. In this example, a current flowing through the coil 62 </ b> A (see FIG. 3) of the motor 61 is supplied through the electric wire 77. In addition, the electric power supplied with the electric wire 77 is not restricted to this. For example, another control signal may be supplied to the motor 61 through the electric wire 77.

  The control board 38 has an L shape when the crankshaft 41 is viewed in the axial direction. That is, the control board 38 has a rectangular portion extending in a certain direction (vertical direction in this example) in the axial direction of the crankshaft 41, and a direction perpendicular to the one direction (in this example) from the rectangular portion. In the front-rear direction). The rectangular portion is disposed between two shafts (in this example, the crankshaft 41 and the gear shaft 81). One of these two shafts (in this example, the gear shaft 81) is arranged to face the rectangle and the protruding portion. That is, one of the two shafts sandwiching the control board 38 is disposed at a position facing the L-shaped cutout portion of the control board 38. Thus, a part of the L-shaped control board 38 is disposed between the two axes. Thereby, compared with the case where the rectangular control board 38 is arrange | positioned between two axes | shafts, the distance between the axes of these two axes | shafts can be shortened, ensuring the area of the control board 38. FIG.

  The shape of the control board 38 is not limited to the L shape. The control board 38 can be in the shape of one of two boards of the same shape formed by cutting the surface of a rectangular original board. Thereby, the distance between two axes can be shortened similarly to the case of the above L-shape. Here, the shape of the control board 38 will be described.

<Control board shape>
FIG. 6 is a view for explaining the shape of the control board 38 shown in FIG. As shown in FIG. 6, the control board 38 has one shape out of two boards of the same shape formed by cutting the surface of the original board of the rectangular ABCD. That is, one of the two substrates (hexagon ABHGFE) formed by cutting the surface of the original substrate of the rectangular ABCD with a cutting line EFGH passing through the two sides AD and BC facing each other is the shape of the control substrate 38. It has become. The cutting line EFGH by this cutting includes a non-parallel line FG that is not parallel to the side AB (or CD) perpendicular to the side AD (or BC) through which the cutting line EFGH of the rectangle ABCD of the original substrate passes.

  In the example shown in FIG. 6, the non-parallel line FG is parallel to the side AD through which the cutting line EFGH of the rectangle ABCD of the original substrate passes. The cutting line EFGH includes lines EF and GH perpendicular to the non-parallel line FG. Further, the cutting line EFGH includes a concave portion EFG that is recessed inward in a direction parallel to the side AD through which the cutting line EFGH of the rectangle ABCD of the original substrate passes.

  The control board 38 shown in FIG. 6 has a shape obtained by cutting out a portion of a rectangle EFGJ having a side that is a part of the sides AJ and JH of the rectangle ANHJ from the rectangle ABHJ. The notched portion is a part of another substrate EFGHCD formed by cutting the rectangular ABCD. Therefore, the cut-out portion EFGJ can be effectively used as the control board 38 of another drive unit having the same shape without being discarded. Thereby, a yield property becomes favorable.

  A part of the control board 38 includes a first shaft and a second shaft, which are two of the crank shaft 41, the motor shaft 64, and the gear shaft 81 (in this example, the first shaft is the gear shaft 81, and the second shaft The shaft is the crankshaft 41). Further, when the first shaft (gear shaft 81) is viewed in the axial direction, the first shaft (gear shaft 81) includes the side AB of the control board 38 facing the cutting line EFGH and the two sides AE connected to the side AB. , BH included in a virtual rectangle ABHJ determined by the longer side BH. Accordingly, the first axis (gear shaft 81) is disposed at a position facing the sides EF and GF perpendicular to each other on the cutting line of the control board 38. That is, the first axis is arranged so as to be surrounded from two directions by two sides of the control board 38 that are orthogonal to each other. As described above, the control board 38 is arranged so that the control board 38 faces the first axis of the two axes sandwiching the control board 38 from two directions so that the first axis is in one direction. Can be arranged more efficiently than arrangements facing each other.

  In the example shown in FIG. 6, the first shaft (gear shaft 81) is formed in the region EFGJ cut out from the substrate ABCD in order to cut out the other substrate EFGHCD out of the two substrates formed by cutting the rectangular ABCD. Be placed. In other words, the portion EFGJ cut out from the substrate for arranging the first shaft (gear shaft 81) can be effectively used as the other of the two substrates without being discarded.

  Here, the side AB of the control board 38 facing the cutting line EFGH is the side of the control board 38 facing the cutting line EFGH crossing the rectangle ABCD of the original board. For example, as shown in FIG. 6, when the cutting line EFGH is a line passing through two opposing sides AD and BC of the rectangle ABCD, the control board 38 among the sides AB and DC perpendicular to these sides AD and BC. Side AB is the side of the control board facing the cutting line EFGH. Also, the two sides connected to this side are portions that form the sides of the control board 38 in the sides AD and BC of the rectangle ABCD through which the cutting line EFGH passes.

  The first shaft (gear shaft 81) is disposed at a position facing the recess EFG of the cutting line EFGH. That is, the control board 38 is disposed so that the recess EFG of the control board 38 surrounds the first shaft (gear shaft 81). Therefore, the arrangement using the space more efficiently becomes possible.

  In the example shown in FIG. 6, the first shaft (gear shaft 81) is arranged at a position included in the rectangle ABHJ when viewed in the axial direction. On the other hand, at least a part of the first axis may be included in the rectangle ABHJ. Here, the axis is grasped in consideration of the radial thickness of the first axis. Therefore, for example, as in the case of the gear shaft 81a shown in FIG. 6, the shaft center that is the rotation center point of the first shaft when viewed from the axial direction of the first shaft is outside the rectangle ABHJ. The first axis may be included in the rectangle ABHJ even when a part of the rectangle is in the rectangle ABHJ.

  Note that the control board 38 is one of two boards having the same shape formed by cutting the surface of the rectangular original board, and is an expression for explaining the shape of the control board 38. The meaning which limits the manufacturing method of 38 is not included. That is, the control board 38 only needs to have a shape that becomes a rectangle or a shape close to a rectangle when combined with another board having the same shape as the control board 38. For example, in the example shown in FIG. 6, the recess EFG of the cutting line EFGH of the control substrate 38 corresponds to the protrusion EFG of another substrate EFGHCD. As described above, one of the shapes each having the concave portion and the convex portion corresponding to each other can be used as the shape of the control board 38.

  As described above, the efficiency of the manufacturing process can be improved by making the shape of the control substrate 38 one of two substrates having the same shape formed by cutting a rectangular substrate as described above. For example, two control substrates 38 can be produced by cutting one rectangular substrate. In addition, a manufacturing process is not restricted to the case of cutting out two control boards from one rectangular sheet (original board | substrate). For example, in the manufacturing process, three or more control boards can be cut out from one rectangular sheet.

  FIG. 7 is a diagram illustrating an example in which four control boards L1 to L4 are cut out from one rectangular sheet. In the example shown in FIG. 7, four control boards L1 to L4 and a discarding board RSCB are cut out from the original sheet rectangle RSLK. Two control boards L1 and L2 are cut out by further cutting a rectangle ABCD formed by cutting the rectangle RSLK with a line AD and a line BC along a cutting line EFGH. By cutting the rectangle KADL along the cutting line MNPQ, two more control boards L3 and L4 are cut out.

  In the example shown in FIG. 7, the corners A, B, C, and D of the rectangle ABCD that are the original substrates of the control substrates L1 and L2 are chamfered. The corners B and D are chamfered by 45 degrees (MT1), and the corners A and C are rounded and chamfered (MR1). Thus, the rectangle used as the original substrate may not be strictly a rectangle. The original substrate may have a notch in a part as long as it has four sides and has a shape close to a rectangle as a whole. Moreover, as shown in FIG. 7, the cutting line may have a certain width.

  Referring again to FIG. 5, a part of the control board 38 is disposed so as to overlap with the gear 82 which is a rotating part of the gear shaft 81 when viewed from the axial direction of the gear shaft 81. Further, a part of the control board 38 overlaps with the rotor 63 (which is disposed further inside the radial inner side 62 u of the stator 62) which is a rotating part of the motor shaft 64 when viewed from the axial direction of the motor shaft 64. . Further, a part of the control board 38 overlaps with a magnet 58 a provided on the outer periphery of the one-way clutch 55 that is a rotating part of the crankshaft 41 when viewed from the axial direction of the crankshaft 41. As described above, the control board 38 is disposed so as to overlap the rotating component of the gear shaft 81, the rotating component of the motor shaft 64, and the rotating component of the crankshaft 41 in the axial direction of the crankshaft 41. Thereby, the control board 38 can be efficiently arranged in the housing 51.

  In addition, the control board 38 has a rotating part of the gear shaft 81 and a rotation of the motor shaft 64 between two shafts sandwiching the control board 38, that is, the gear shaft 81 which is the first shaft and the crank shaft 41 which is the second shaft. The parts and the rotating parts of the crankshaft 41 overlap the axial direction of the crankshaft 41. Thereby, components can be efficiently arranged between the two axes of the control board 38. Therefore, the space can be used more efficiently. As a result, the distance between the first axis and the second axis can be reduced. The gear shaft 81 is disposed in a region cut out from the original rectangular substrate. The control board 38 has a shape having a notch for arranging the gear shaft 61. Here, the notched portion can be a part of the other of the two substrates formed by cutting the original substrate. Therefore, the yield is improved.

  Further, the control board 38 has a rotating part (gear 82) of the first axis (gear shaft 81) of the two axes sandwiching the control board 38, and the first axis above and in front of the first axis in the in-vehicle state. They are arranged so as to overlap when viewed in the axial direction. Note that the control board 38 does not always have to overlap all of the rotating parts of the gear shaft 81, the rotating parts of the motor shaft 64, and the rotating parts of the crankshaft 41. The control board 38 may be configured to overlap at least one of these rotating components.

  A part of the control board 38 overlaps with a magnet 58a that is one of rotating parts that rotate together with the crankshaft 41 in the axial direction. On the control board 38, an encoder 58b is arranged at a position overlapping with the rotation path of the magnet 58a when the crankshaft 41 rotates in the axial direction. The encoder 58b is an example of a sensor (rotation detection element) for detecting the rotation of the crankshaft 41. The magnet 58a is an example of an element to be detected. As the crankshaft 41 and the one-way clutch 55 (outer member 55b) rotate together, the magnetic field generated by the magnet 58a changes. The encoder 58b detects this magnetic field change. The encoder 58b can output the change in the magnetic field as a pulse signal to the control board 38. The encoder 58b and the magnet 58a constitute a crank rotation detector 58.

  As described above, in the example shown in FIG. 5, a part of the control board 38 and a part of the rotating component of the crankshaft 41 are arranged so as to overlap in the axial direction view. Further, a detection element (encoder 86b) is arranged at a portion overlapping the rotating component of the crankshaft 41 of the control board 38, and a detected element (magnet) is arranged at a portion of the rotating component of the crankshaft 41 overlapping the control board 38. 58a) is arranged. Accordingly, the volume occupied by the crank rotation detection unit in the housing 51 can be reduced as compared with the case where the detection element is provided independently of the control board 38.

  The control board 38 is disposed so as to be positioned over two shafts, that is, between the crank shaft 41 and the gear shaft 81 and above the gear shaft 81 in a state where the drive unit 40 is mounted on the battery-assisted bicycle 1. . Further, a lead-in port 53 </ b> V through which the electric wires 37 a and 37 b for supplying electric power to the motor 61 from the outside of the housing 51 are drawn into the housing 51 is also provided above the drive unit 40. The electric wires drawn into the housing 51 from the drawing port 53V are connected to the control board 38. In the region of the control board 38 located between the gear shaft 81 and the drawing port 53V, the electric wire drawn from the drawing port 53V is connected to the control board 38.

  In the example illustrated in FIG. 5, one side of the control board 38 is disposed so as to face the drawing port 53 </ b> V. Thereby, the length of an electric wire can be shortened until it connects to the control board 38 from the drawing-in port 53V. Further, by providing the lead-in port 53V above the drive unit 40, the length of the electric wire connecting the battery unit 35 and the drive unit 40 provided above the drive unit 40 can also be shortened.

  A part of the control board 38 is arranged between the crankshaft 41 and the gear shaft 81 at a position overlapping with a part of the motor 61 in the axial direction of the crankshaft 41. Thus, the motor 61 is arranged between the crankshaft 41 and the gear shaft 81, and the control board 38 is arranged so that a part of the motor 61 and a part of the control board 38 overlap when viewed in the axial direction. be able to. Here, the control board 38 can be arranged in accordance with the efficient arrangement of the motor 61, the gear 82, and the crankshaft 41. That is, since the control board 38 has a non-rectangular shape as described above, the control board 38 can be arranged so as not to restrict the positional relationship among the crankshaft 41, the motor 61, and the gear 82.

  In the example shown in FIG. 5, the motor 61 is disposed between two shafts that extend outward through the wall of the housing 51, that is, the crank shaft 41 and the gear shaft 81. The motor shaft 64 of the motor 61 is stored in the housing 51 and does not come out (see FIG. 3). Therefore, by disposing the motor 61 between the crankshaft 41 and the gear shaft 81, the housing 51 can be reduced in size. Furthermore, since the distance between the crankshaft 41 and the gear shaft 81 is not restricted by the control board 38, it can be made as small as allowed by design.

  It is also conceivable to use the space efficiently by dividing the control board 38 into a plurality of boards and distributing them in the housing. In this case, an electric wire for connecting the plurality of divided substrates is required. On the other hand, according to the shape and arrangement of the control board 38 of the present embodiment, efficient arrangement is possible without increasing the number of electric wires.

[Configuration example of the second case]
FIG. 8 is a plan view of the second case 52 as viewed from the mating surface 52A side with the first case 53. FIG. In FIG. 8, the part where the first case 53 and the second case 52 are in contact, that is, the mating surface 52A of the second case 52 with the first case 53 is indicated by hatching. The second case 52 is provided with a shaft hole 52a through which the crankshaft 41 passes and a hole 52b through which the gear shaft 81 passes. A mating surface 52 A of the second case 52 with the first case 53 is formed along the outer shape of the drive unit 40 in a cross section perpendicular to the crankshaft 81. That is, the outer edge of the mating surface 52 </ b> A is exposed to the outside of the drive unit 40. In the surface of the mating surface 52A, a plurality of holes 52c1 to 52c8 into which fasteners for fastening the first case 53 and the second case 52 are inserted, and fasteners for fixing the drive unit 40 to the bracket 15. A plurality of through holes 52e1 to 52e3 are provided. The holes 52c1 to 52c8 may be through holes or non-through holes. In the second case 52, the portion where the holes 52c1 to 52c8 and the through holes 52e1 to 52e3 are provided has a thickness of the first case larger than the surroundings corresponding to the holes.

  In a state where the first case 53 and the second case 52 are in contact with each other at the mating surface 52A, one fastening fitting is inserted into the hole 52c1 of the second case 52 and the hole 53h1 (see FIG. 4) of the first case 53. Similarly, fasteners are inserted into the holes 52c2 to 52c8 of the second case 52 and the holes 53h2 to 53h8 (see FIG. 4) of the first case 53, respectively. In addition, a fastener for fixing the drive unit 40 to the bracket 15 is inserted into the through hole 52e1 of the second case 52 and the through hole 53j1 (see FIG. 4) of the first case 53. Similarly, fasteners for fixing the drive unit 40 to the bracket 15 are inserted into the through holes 52e2 and 52e3 of the second case 52 and the through holes 53j2 and 53j3 (see FIG. 4) of the first case 53, respectively.

  In the second case 52, a portion 52V corresponding to a drawing-in port 53V (see FIG. 4) into which an electric wire from the outside of the housing 51 is drawn is flush with the mating surface 53A. That is, a portion 52V that is the same surface as the mating surface 52A and is sandwiched between the mating surfaces 52A above the second case 52 in the in-vehicle state corresponds to the concave portion of the first case 53 (see 53V in FIG. 4). Is provided. A sealing agent that adheres the first case 53 and the second case 52 to each other can be applied to the mating surface 52A and the portion 52V.

[Modification of control board shape]
FIG. 9 is a view showing one of the modified examples of the shape of the control board 38. In the example shown in FIG. 9, the control board 38 has a shape formed by cutting the rectangle ABCD along a straight line EH that passes through the side AD and the side BC of the rectangle ABCD and is not parallel to the side AB. The cutting line EH passes through the center O of the rectangle ABCD. In this case, the line EH is a non-parallel line. The first axis (for example, the gear shaft 81) is included in the rectangle ABHJ determined by the side AB of the control board 38 facing the cutting line EH and the longer side BH among the sides connected to the side AB. A control board 38 is arranged.

  As a further modification of the example shown in FIG. 9, one of two substrates formed by cutting a rectangular ABCD along a line connecting diagonal vertices A and C may be the shape of the control substrate 38. it can. In this case, the shape of the control board 38 is a triangle ABC. The first axis is arranged in a rectangle ABDC determined by a side AB facing the cutting line AC and a side BC connected to the side AB.

  FIG. 10 is a diagram illustrating another modification of the shape of the control board 38. In the example shown in FIG. 10, the cutting line EH has a curved shape. In this example, the cutting line EH passes through the point E on the side AD of the rectangle ABCD, the center O of the rectangle ABCD, and the point H on the side BC. From the point E on the side AD of the cutting line EH to the center O is a convex curve inside the control board 38, and from the center O to the point H on the side BC is a convex curve outward. In this case, the first axis is arranged in a rectangle ABHJ determined by the side AB facing the cutting line EH and the longer side BH among the sides connected to this side.

  The cutting line is not necessarily one. FIG. 11 is a diagram showing still another modification of the shape of the control board 38. In the example shown in FIG. 11, a cutting line extending in parallel to the side AB from the point E on the side AD to the inside of the rectangle ABCD is straight and straight at a point L on the way to the point F. Branches to the line leading to K. Further, a cutting line FG extending from the point F to the side DC parallel to the side BC and a cutting line KG extending from the point K to the side BC parallel to the side AB merge at the point G. A cutting line GH extends from the point G to the side BC in parallel with the side AB. In this way, the region including the center O can be avoided and cut. The first axis is arranged in a rectangle ABHJ determined by the side AB of the control board 38 facing the cutting line ELFGH and the longer side BH among the sides connected to the side AB. Also in this case, although the region LFGK including the center O is not used as a substrate, the same effect as that of the control substrate 38 having the shape shown in FIG. 6 can be obtained.

  That is, also in the example shown in FIG. 11, the control board 38 has a shape having a notch EFGJ (recess EFG) for arranging the first shaft (gear shaft 81), and a part of the notch EFGJ. However, the shape can be used as a part of the control board 38 of another drive unit. For this reason, it is possible to achieve both reduction in size of the drive unit 40 and securing of yield. Note that the region where the first axis is disposed is not necessarily within the region of the other substrate ELKHCD among the two substrates formed by cutting the rectangular ABCD. For example, like the gear shaft 81a in FIG. 11, the first shaft can be arranged in a region LFGK that does not become a part of another substrate ELKHCD in the notch EFGJ.

[Modification of control board layout]
Next, a modified example of the arrangement of the control board 38 will be described with reference to FIGS. In FIGS. 12 to 14, an arrow between “up and down” and an arrow between “front and rear” orthogonal thereto indicate the directions of up and down and front and rear when the drive unit 40 is mounted on the battery-assisted bicycle 1. Yes.

  FIG. 12 is a diagram illustrating a modification of the arrangement of the control board 38 and the two shafts that sandwich the control board 38. In the example shown in FIG. 12, the control board 38 is disposed in front of and below the first shaft (as an example, the gear shaft 81) in the vehicle-mounted state of the drive unit 40. The non-parallel line GF of the cutting line of the control board 38 faces the first axis from below, and the cutting line EF parallel to the side AB faces the first axis from the front. Further, the second shaft (for example, the crankshaft 41) is disposed in front of the control board 38. The side AB of the control board 38 is opposed to the second axis from the rear.

  FIG. 13 is a diagram showing another modification of the arrangement of the control board 38 and the two axes. In the example illustrated in FIG. 13, the control board 38 is disposed above and in front of the first shaft (as an example, the gear shaft 81) in the vehicle-mounted state of the drive unit 40. The non-parallel line GF of the cutting line of the control board 38 is opposed to the first axis from the front, and the cutting line EF parallel to the side AB is opposed to the first axis from above. Further, the second shaft (crank shaft 41 as an example) is disposed above the control board 38. The side AB of the control board 38 faces the second axis from below.

FIG. 14 is a view showing still another modified example of the arrangement of the control board 38 and the two shafts. In the example shown in FIG. 14, the control board 38 is disposed opposite and below the first shaft (in this example, the crankshaft 41) in the on-vehicle state of the drive unit 40. The non-parallel line GF of the cutting line of the control board 38 faces the first axis from the rear, and the cutting line EF parallel to the side AB faces the first axis from below. Further, the second shaft (for example, the gear shaft 81) is disposed behind the control board 38. The side BH of the control board 38 is opposed to the second axis from the front.
[Effect of the embodiment]

  The drive unit 40 in the above embodiment is a drive unit used for a battery-assisted bicycle, and includes a housing 51, a crankshaft 41 penetrating the housing 51, a motor 61 housed in the housing 51 and having a motor shaft 64. The gear 82 is housed in the housing 51 and meshed with the motor shaft 64 of the motor 61, the gear shaft 81 provided with the gear 82, and the housing 51 in a plane substantially perpendicular to the axial direction of the crankshaft 41. The control board 38 is provided. The control board 38 is one of two boards having the same shape formed by cutting the surface of a rectangular (including square) original board. The cutting lines resulting from this cutting include the non-parallel lines GF that are not parallel to the sides AB and CD that are perpendicular to the sides AD and BC through which the cutting line of the rectangle ABCD of the original substrate passes. A part of the control board 38 is disposed between the first shaft and the second shaft, which are two of the crank shaft 41, the motor shaft 64, and the gear shaft 81. When the first axis is viewed in the axial direction, at least a part of the first axis is a virtual one determined by the side of the control board 38 facing the cutting line and the longer side of the two sides connected to the side. Contained within a rectangle.

  According to the above configuration, the control substrate 38 is formed of one of two substrates having the same shape formed by cutting the surface of a rectangular substrate. In this case, the cut is made such that a non-parallel line FG that is not parallel to the side AB perpendicular to the sides AD and BC through which the cutting line EFGH of the rectangle ABCD of the original substrate passes is included in the cutting line. Thereby, for example, two control boards can be cut out by cutting one rectangular ABCD board. Therefore, the control board 38 having a non-rectangular shape can be efficiently manufactured by a simple manufacturing process.

  The control board 38 is disposed between at least two of the crank shaft 41, the motor shaft 64, and the gear shaft 81. Further, one of the two shafts sandwiching the control board 38 is the side AB of the control board 38 facing the cutting line as viewed from the axial direction of the crankshaft 41 and the two sides AE and BH connected to this side. It is included in the rectangle ABHJ determined by the longer side BH. That is, the non-parallel line GF is disposed so as to face either of the two axes sandwiching the control board 38. Thereby, compared with the case where a rectangular board | substrate is arrange | positioned between two axes | shafts, even if the area of the same board | substrate, the distance between the axes of two axes | shafts can be shortened. Further, since the control board 38 is efficiently manufactured by a simple manufacturing process, it is possible to ensure the yield. As a result, it is possible to reduce the size of the drive unit 40 while ensuring the yield.

  Note that the case where the first axis is included in the rectangle ABHJ is not limited to the case where the axis of the first axis is included in the rectangle ABHJ when the crankshaft 41 is viewed in the axial direction. For example, even when the axis of the first axis is outside the rectangle ABHJ and a part of the cross section of the first axis is located in the rectangle ABHJ, the first axis can be included in the rectangle ABHJ.

  The cutting line EFGH of the control board 38 may include a recess EFG that is recessed inward in a direction parallel to the sides AD and BC through which the rectangular cutting line of the original board passes. The control board 38 is disposed such that the recess EFG faces the first axis when the first axis (for example, the gear shaft 81) is viewed in the axial direction. With the above configuration, one of the two axes arranged with the control board 38 interposed therebetween, that is, the first axis can be arranged so as to be surrounded by the recess EFG of the control board 38. Therefore, the arrangement using the space more efficiently becomes possible.

  The cutting line EFGH may include the non-parallel line GF parallel to the sides AD and BC through which the cutting line EFGH of the rectangle ABCD of the original substrate passes, and the vertical line EF perpendicular to the non-parallel line GF. With the above configuration, one of the two axes arranged with the control board 38 interposed therebetween may be arranged so as to be surrounded by the non-parallel line GF of the cutting line of the control board 38 and the vertical line EF perpendicular thereto. it can. Therefore, the arrangement using the space more efficiently becomes possible. Moreover, since the cutting line includes only a line parallel to any side of the rectangle ABCD of the original substrate, the cutting process can be simplified.

  Each of the crankshaft 41, the motor shaft 64, and the gear shaft 81 may be provided with a rotating component that rotates together with the shaft. The control board 38 can be disposed so as to have a portion that overlaps the rotating component of at least one of the first axis and the second axis when viewed from the axial direction of the first axis. With this configuration, the control board and the rotating component can be arranged so as to overlap in the axial direction view. Therefore, the space can be used more efficiently.

  The portion of the control board 38 that overlaps with the rotating component can be located between the first axis and the second axis when viewed in the axial direction of the first axis. Thereby, the control board 38 and the rotating component can be efficiently arranged between the first axis and the second axis. Therefore, the space can be used more efficiently.

  The crankshaft 41 may include a rotating component (for example, the one-way clutch 55) that rotates together with the crankshaft 41 and a detected element (for example, a magnet 58a) provided in the rotating component. The control board 38 is disposed at a position overlapping the rotating component of the crankshaft 41 when viewed in the axial direction of the crankshaft. The control board 38 is provided with a rotation detection element (for example, an encoder 58b) disposed at a position overlapping the path of the detected element 58a when the rotating component rotates as viewed in the axial direction. Thereby, a rotation detection element can be provided in the control board 38 which overlaps with a rotation component. Therefore, the space can be used more efficiently. Further, it is not necessary to provide a special control board for arranging the rotation detecting element.

  The first axis and the second axis sandwiching the control board 38 may be axes that penetrate the housing 51 and extend to the outside of the housing 51. With this configuration, it is possible to arrange the control board using the space efficiently. For example, the control board 38 can be disposed at a position overlapping with an axis that does not penetrate the housing 51, that is, an axis other than the first axis and the second axis as viewed in the axial direction. Thereby, the freedom degree of design of the arrangement position of the control board 38 increases. As a result, it is possible to arrange the control board efficiently.

  The battery-assisted bicycle 1 including the drive unit 40 is also one embodiment of the present invention.

  While the embodiments of the present invention have been described above, the above-described embodiments are merely examples for carrying out the present invention. Therefore, the present invention is not limited to the above-described embodiment, and can be implemented by appropriately modifying the above-described embodiment without departing from the spirit thereof.

  In the above example, the rotation of the motor 61 is transmitted to the gear shaft 81 and the auxiliary sprocket 43 attached to the gear shaft 81 rotates. In contrast, for example, the rotation of the motor 61 can be transmitted to the crankshaft via a gear.

  In the above example, the two axes sandwiching the control board 38 are the gear shaft 81 and the crankshaft 41. The two axes on which the control board 38 is disposed are not limited to this combination.

Claims (9)

A drive unit used for a battery-assisted bicycle,
A housing;
A crankshaft penetrating the housing;
A motor housed in the housing and having a motor shaft;
A gear housed in the housing and meshed with a motor shaft of the motor;
A gear shaft provided with the gear;
A control board disposed in a plane substantially perpendicular to the axial direction of the crankshaft in the housing,
The control board is one of two boards of the same shape formed by cutting a rectangular (including a square, hereinafter the same) original substrate surface, and the cutting line by the cutting is a line of the original board. A non-parallel line that is not parallel to a side perpendicular to the side through which the cutting line of the rectangle passes,
A part of the control board is disposed between a first shaft and a second shaft, which are two of the crank shaft, the motor shaft, and the gear shaft, and is viewed in the axial direction of the first shaft. At least a part of the first axis is included in a virtual rectangle determined by a side of the control board facing the cutting line and a longer side of two sides connected to the side. Drive unit. The drive unit according to claim 1,
The cutting line of the control board includes a recess recessed inward in a direction parallel to a side through which the rectangular cutting line of the original board passes,
The control board is a drive unit that is disposed such that the recess faces the first axis when viewed in the axial direction of the first axis. The drive unit according to claim 1 or 2,
The cutting unit includes the non-parallel line that is parallel to a side through which the rectangular cutting line of the original substrate passes, and a vertical line that is perpendicular to the non-parallel line. The drive unit according to any one of claims 1 to 3,
Each of the crankshaft, the motor shaft, and the gear shaft is provided with a rotating component that rotates together with the shaft,
The control board has a drive unit having a portion that overlaps with a rotating component of at least one of the first axis and the second axis when viewed from the axial direction of the first axis. The drive unit according to claim 4,
The portion of the control board that overlaps with the rotating component is located between the first axis and the second axis when viewed in the axial direction of the first axis. The drive unit according to any one of claims 1 to 5,
The crankshaft has a rotating component that rotates together with the crankshaft, and a detected element provided in the rotating component,
The control board is disposed at a position overlapping the rotating component of the crankshaft when viewed in the axial direction of the crankshaft,
The drive unit, wherein the control board is provided with a rotation detection element arranged at a position overlapping with a path of the detection element when the rotary component rotates as viewed in the axial direction. The drive unit according to any one of claims 1 to 6,
The drive unit, wherein the first shaft and the second shaft are shafts that pass through the housing and extend to the outside of the housing. The drive unit according to any one of claims 1 to 7,
The housing further includes a lead-in port for drawing an electric wire for supplying electric power to the motor from the outside of the housing into the housing;
The control board is disposed between the first shaft and the second shaft and above the first shaft in a state where the drive unit is mounted on the battery-assisted bicycle.
The pull-in port is provided above the drive unit in a state where the drive unit is mounted on the battery-assisted bicycle,
A drive unit in which an electric wire drawn into the housing from the drawing port is connected to the control board.   A battery-assisted bicycle comprising the drive unit according to any one of claims 1 to 8.

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