JP2020019414A - In-wheel motor drive device - Google Patents

Abstract

To provide an in-wheel motor drive device which enables a wheel speed detection part including a pulser ring and a rotation sensor to be arranged without affecting a length of the in-wheel motor drive device as seen in an axle direction and enables a gap between a detected part of the pulser ring and the rotation sensor to be accurately checked.SOLUTION: A wheel speed detection part (50) of an in-wheel motor drive device (1) includes: a pulser ring (51) having a detected part (52) disposed within a hat part (90) of a brake rotor (BD) and attached coaxially with a rotary ring (12) of a wheel hub bearing part (11); and a rotation sensor (54) which is attached to a fixed portion (10) so as to face the detected part (52) of the pulser ring (51).SELECTED DRAWING: Figure 6

Description

  The present invention relates to an in-wheel motor drive device, and more particularly to an in-wheel motor drive device provided with a wheel speed detection unit that detects rotation of a wheel.

  In recent years, vehicles equipped with an ABS (anti-lock brake system) have been increasing in order to improve safety. In the ABS, a wheel speed detecting device that detects rotation of a wheel is used. The wheel speed detection device includes a sensor target provided on a rotating portion that rotates integrally with the wheel, and a rotation sensor (wheel speed sensor) attached to face the sensor target. The detection signal of the rotation sensor is transmitted to a control device mounted on the vehicle body side, and the control device controls the brake mechanism such as adjusting the brake hydraulic pressure of the wheels. Such a rotation sensor is used not only for ABS but also for ESC (side skid prevention device).

  Japanese Patent Application Laid-Open No. 2013-152023 (Patent Document 1) discloses a configuration in which a pulsar ring (sensor target) is disposed in a hat portion of a brake disk. In the cited document 1, the pulsar ring includes a flange portion that extends in the radial direction and is attached to the hat portion, and a detected portion that is bent from the flange portion, extends in the axle direction, and faces the rotation sensor.

JP 2013-152023 A

  To avoid interference between the in-wheel motor drive and the inner wall of the wheel housing formed on the outside in the vehicle width direction of the vehicle body without sacrificing the interior space, shorten the length of the in-wheel motor drive in the axle direction. There is a need to. In addition, when the in-wheel motor drive device is mounted on the steered wheels, the arrangement of the device without sacrificing the steered angle requires a longer axle length than the non-steered wheels. Need to be even shorter.

  The configuration in which the pulsar ring is disposed in the hat portion of the brake disk as in Patent Document 1 is advantageous in that it does not affect the axial length of the in-wheel motor drive device.

  In Patent Literature 1, a position adjustment unit is provided on a holding member that holds a rotation sensor, and a gap between a detected portion of the pulsar ring and the rotation sensor can be adjusted. Errors can be tolerated. As a result, a decrease in the detection accuracy of the rotation sensor can be prevented.

  However, when the brake disk is attached to the in-wheel motor drive device, the hat portion of the brake disk is a closed space, so that the gap between the detected portion of the pulsar ring and the rotation sensor cannot be directly adjusted. . Therefore, in Patent Literature 1, it is necessary to adjust the gap using a jig, and the number of steps for attaching and detaching the jig is required. In addition, since the position of the jig and the actual detected portion are different, accurate gap adjustment is difficult.

  The present invention has been made in order to solve the above-described problems, and an object of the present invention is to provide a wheel speed detecting unit including a pulsar ring and a rotation sensor in the axle direction length of an in-wheel motor drive device. It is an object of the present invention to provide an in-wheel motor drive device which can be arranged without any influence and which can accurately adjust an interval (air gap) between a detected portion of a pulsar ring and a rotation sensor.

  An in-wheel motor drive device according to an aspect of the present invention is a vehicle motor drive device disposed inside a wheel, and is coaxial with a brake rotor and a wheel having a hat portion formed so as to be depressed outward in the vehicle width direction. A wheel hub bearing section including a rotating wheel coupled to the vehicle, and a wheel speed detecting section for detecting rotation of the wheel. The wheel speed detecting section has a detected section disposed in the hat section of the brake rotor, and the pulsar ring mounted coaxially with the rotating wheel of the wheel hub bearing section, so as to face the detected section of the pulsar ring. , A rotation sensor attached to the fixed part.

  The rotating wheel of the wheel hub bearing has a hub flange projecting radially outward. The pulsar ring is desirably fixed to the hub flange by a screw member. The screw member includes a fastening member such as a screw, a bolt, and a screw.

  When the hub flange is composed of a plurality of protrusions arranged at intervals from each other in the circumferential direction and a plurality of valleys located between the protrusions, the pulsar ring includes a plurality of valleys of the hub flange. More preferably, it is fixed at at least two places.

  Alternatively, the pulsar ring may be fixed while being pressed into the hub flange.

  The in-wheel motor driving device further includes a motor unit including a motor rotation shaft that drives a rotating wheel of the wheel hub bearing unit, and a casing that houses the motor unit. The rotation sensor may be attached to a casing, a fixed portion of the wheel hub bearing, or a hub supporting member that supports the wheel hub bearing.

  Preferably, the rotation sensor is held by a holding member fixed to the fixed portion.

  It is desirable that the in-wheel motor drive device further includes a heat shield plate disposed between the rotation sensor and the brake rotor.

  According to the present invention, the wheel speed detecting section including the pulsar ring and the rotation sensor can be arranged without affecting the length of the in-wheel motor drive device in the axle direction. In addition, it is possible to accurately adjust the distance between the detected portion of the pulsar ring and the rotation sensor.

FIG. 2 is a developed cross-sectional view showing a basic configuration of the in-wheel motor drive device according to Embodiment 1 of the present invention. FIG. 2 is a schematic sectional view showing the inside of the in-wheel motor drive device according to Embodiment 1 of the present invention. FIG. 2 is a front view schematically showing a basic configuration of the in-wheel motor drive device according to Embodiment 1 of the present invention. FIG. 3 is a longitudinal sectional view schematically showing a wheel hub bearing according to Embodiment 1 of the present invention. It is a front view which shows typically the mounting structure of the wheel speed detection part in Embodiment 1 of this invention. FIG. 2 is a cross-sectional view schematically illustrating a mounting structure of a wheel speed detecting unit according to Embodiment 1 of the present invention. FIG. 3 is an external perspective view of a holding member that holds the rotation sensor according to the first embodiment of the present invention. FIG. 4 is a cross-sectional view of a holding member that holds the rotation sensor according to the first embodiment of the present invention. FIG. 5 is a cross-sectional view schematically illustrating a mounting structure of a wheel speed detection unit according to a first modification of the first embodiment of the present invention. FIG. 5 is a front view schematically showing a mounting structure of a wheel speed detection unit according to a first modification of the first embodiment of the present invention. FIG. 10 is a front view schematically showing a state in which the heat shield plate is fixed to the casing in Modification Example 2 of Embodiment 1 of the present invention. FIG. 13 is a cross-sectional view schematically showing a state in which a heat shield plate is fixed to a casing in Modification Example 2 of Embodiment 1 of the present invention. FIG. 9 is a cross-sectional view schematically illustrating a mounting structure of a wheel speed detection unit according to a second embodiment of the present invention. It is a front view which shows typically the mounting structure of the wheel speed detection part in Embodiment 2 of this invention. FIG. 14 is a cross-sectional view schematically illustrating a mounting structure of a wheel speed detection unit according to a modification of the second embodiment of the present invention. It is a front view which shows typically the mounting structure of the wheel speed detection part in the modification of Embodiment 2 of this invention. It is a front view which shows typically the other attachment structure of the wheel speed detection part in the modification of Embodiment 2 of this invention.

  Embodiments of the present invention will be described in detail with reference to the drawings. In the drawings, the same or corresponding portions have the same reference characters allotted, and description thereof will not be repeated.

  The in-wheel motor drive device according to the present embodiment is a vehicle motor drive device disposed inside wheels. The wheels are drive wheels of a passenger vehicle such as an electric vehicle or a hybrid vehicle.

<First Embodiment>
(Example of basic configuration of in-wheel drive device)
With reference to FIGS. 1 to 4, an example of a basic configuration of an in-wheel motor driving device 1 according to the present embodiment and a peripheral structure thereof will be described. In these drawings, the illustration of the wheel speed detection unit is omitted. FIG. 1 is a developed sectional view showing an in-wheel motor drive device 1 according to Embodiment 1 of the present invention. In FIG. 1, the right side of the drawing represents the inside in the vehicle width direction (inboard side), and the left side of the drawing represents the outside in the vehicle width direction (outboard side). The cross section shown in FIG. 1 is a developed plane in which a plane including the axis M and the axis N shown in FIGS. 2 and 3 and a plane including the axis N and the axis O are connected in this order.

  FIG. 2 is a schematic cross-sectional view showing the inside of the same embodiment, and shows a state in which the in-wheel motor driving device 1 is cut along II-II in FIG. 1 and the cross section is viewed in the direction of the arrow. FIG. 3 is a schematic front view showing the same embodiment, and shows a state in which the in-wheel motor driving device 1 is viewed from the outside in the vehicle width direction. In FIG. 2, each gear is represented by a tip circle in order to avoid complexity of the drawing. 2 and 3, the right side of the paper represents the front of the vehicle, the left side of the paper represents the rear of the vehicle, the upper side of the paper represents the upper side of the vehicle, and the lower side of the paper represents the lower side of the vehicle. 2 and 3, the vehicle is viewed from the outside in the vehicle width direction (outboard side) to the inside in the vehicle width direction (inboard side) in the direction of the axis O.

  FIG. 4 is a longitudinal sectional view showing the wheel hub bearing of the embodiment, and shows a cut surface when the wheel hub bearing is cut along a plane including the axis O. For simplicity of the drawing, FIG. 4 shows only half of the brake disc and the road wheel (wheel wheel).

  As shown in FIG. 1, an in-wheel motor driving device 1 includes a wheel hub bearing 11 provided at the center of a wheel (not shown), a motor 21 for driving the wheel, and a wheel hub bearing for reducing the rotation of the motor. A speed reduction unit 31 that transmits the power to the unit 11. The motor section 21 and the reduction section 31 are arranged offset from the axis O of the wheel hub bearing section 11. The axis O extends in the vehicle width direction and coincides with the axle. With respect to the position in the direction of the axis O, the wheel hub bearing 11 is disposed on one side (outboard side) of the in-wheel motor drive device 1 in the axial direction, and the motor portion 21 is disposed on the other side (inboard side) of the in-wheel motor drive device 1 in the axial direction. , And the speed reduction unit 31 is disposed on one axial side of the motor unit 21, and the axial position of the reduction unit 31 overlaps the axial position of the wheel hub bearing 11.

  The in-wheel motor drive device 1 is a vehicle motor drive device that drives wheels of an electric vehicle. The in-wheel motor drive 1 is connected to a vehicle body (not shown).

  The wheel hub bearing 11 is a rotating inner ring / fixed outer ring, and has an inner ring 12 as a rotating wheel (hub wheel) coupled to a wheel wheel (not shown), and a fixed wheel disposed coaxially on the outer diameter side of the inner ring 12. It has an outer ring 13 and a plurality of rolling elements 14 arranged in an annular space between the inner ring 12 and the outer ring 13.

  Referring to FIG. 1, outer ring 13 passes through opening 39 p formed in front portion 39 f of main body casing 39. The main body casing 39 refers to a casing including an outer shell of the speed reduction unit 31, and accommodates a rotation element of the speed reduction unit 31. The front portion 39f is a casing wall that covers one end of the main body casing 39 in the direction of the axis O of the reduction portion 31. A cylindrical portion 39c is formed in the front portion 39f along the opening edge of the opening 39p. The cylindrical portion 39c protrudes from the outer wall surface of the front portion 39f in one direction of the axis O.

  A plurality of outer ring projections 13g are further provided on the outer peripheral surface of the outer ring 13 at different positions in the circumferential direction. A cylindrical region of the outer ring 13 on the other side of the outer ring protrusion 13g in the axis O direction is inserted into the opening 39p of the front portion 39f. At this time, the other surface of the outer ring projection 13g in the direction of the axis O abuts on the tip of the cylindrical portion 39c, and the outer ring 13 is positioned in the direction of the axis O.

  A through hole 13h is formed in each outer ring protrusion 13g that protrudes in the outer diameter direction. A hub attachment 61 is arranged adjacent to the other side of the outer ring projection 13g in the direction of the axis O. The hub attachment 61 has a center hole, into which the cylindrical portion 39c of the main body casing 39 is inserted. At this time, the outer peripheral surface of the cylindrical portion 39c fits with the inner peripheral surface 61n of the hub attachment 61. The hub attachment 61 is interposed between each outer ring projection 13g on one side in the axis O direction and the front surface portion 39f on the other side in the axis line O direction.

  The hub attachment 61 has a plurality of female screw holes 61f. The female screw holes 61f are formed in the inner diameter side portion of the hub attachment 61, and a plurality of female screw holes are arranged at intervals in the circumferential direction. Each female screw hole 61f of the hub attachment 61 and each through hole 13h of the outer ring 13 extend parallel to the axis O and coincide with each other. A first bolt 62 is passed through the through-hole 13h of the outer ring 13 and the female screw hole 61f of the hub attachment 61 from one side in the direction of the axis O, and a shaft portion of the first bolt 62 passes through the through-hole 13h of the outer ring 13 to form a hub attachment. The female screw hole 61f is screwed into the female screw hole 61, and the head of the first bolt 62 contacts the outer ring projection 13g. Thus, the outer ring 13 is securely attached and fixed to the hub attachment 61 by the first bolt 62.

  The inner ring 12 is a tubular body longer than the outer ring 13, and is passed through a center hole of the outer ring 13. A hub flange 12f is formed at one end of the inner ring 12 protruding from the outer ring 13 to the outside of the in-wheel motor drive device 1 in the direction of the axis O. When viewed from the front, the hub flange 12f has a petal shape. The hub flange 12f has a plurality of protrusions (coupling portions) 12a provided at intervals in the circumferential direction and a plurality of valleys located between the protrusions. And a portion 12b. The protruding portion 12a of the hub flange 12f constitutes a coupling seat for coaxially coupling with the brake disc BD and a wheel (not shown). The inner ring 12 is connected to the wheel by the protrusion 12a of the hub flange 12f, and rotates integrally with the wheel.

  A plurality of rows of rolling elements 14 are arranged in an annular space between the inner ring 12 and the outer ring 13. The outer peripheral surface at the center of the inner ring 12 in the direction of the axis O forms an inner raceway surface of the plurality of rolling elements 14 arranged in the first row. An inner race 12r is fitted around the outer periphery of the other end of the inner race 12 in the direction of the axis O. The outer peripheral surface of the inner race 12r constitutes the inner race surface of the plurality of rolling elements 14 arranged in the second row. The inner peripheral surface at one end of the outer ring 13 in the direction of the axis O forms an outer raceway surface of the rolling elements 14 in the first row. The inner peripheral surface of the other end of the outer ring 13 in the direction of the axis O forms an outer raceway surface of the rolling elements 14 in the second row. In the annular space between the inner ring 12 and the outer ring 13, a seal member 16 is further interposed. The sealing material 16 seals both ends of the annular space to prevent dust and foreign matter from entering. The output shaft 38 of the speed reducer 31 is inserted and fitted into the center hole of the inner ring 12 at the other end in the direction of the axis O. Such fitting is spline fitting or serration fitting.

  FIG. 3 shows a brake disc BD coupled to the inner wheel 12 of the in-wheel motor drive device 1 and a road wheel W of the wheel. The in-wheel motor driving device 1 is housed in an inner space area of the road wheel W. However, the motor section 21 may protrude from the inner space area of the road wheel W to the inside in the vehicle width direction.

  The outer diameter of the inner ring 12 is maximized at the protruding portion 12a and minimized at the valley portion 12b (a portion located between the coupling portions 12f, 12f adjacent in the circumferential direction). The outer diameter of the outer ring 13 is maximized at the outer ring protrusion 13g. The outer diameter of the outer ring 13 is minimized between the outer ring protrusions 13g adjacent in the circumferential direction. The maximum outer diameter of the inner ring 12 and the outer ring 13 is smaller than the inner diameter of the road wheel W.

  As shown in FIG. 3, the hub attachment 61 is formed with a protruding portion 61g that protrudes in the outer diameter direction. A plurality of protrusions 61g are arranged at intervals in the circumferential direction. In the present embodiment, the protrusion 61g becomes thinner toward the outer diameter side in the present embodiment, and the hub attachment 61 has a star shape. With respect to the axis O, it is located on the outer diameter side with respect to the outer ring projection 13g. Thereby, the hub attachment 61 is made larger in diameter than the outer ring 13.

  As shown in FIGS. 1 and 4, a female screw hole 61 h extending parallel to the axis O is formed in each protrusion 61 g. A through hole 39h is formed in the front portion 39f located on the other side of the hub attachment 61 in the direction of the axis O. The through-hole 39h and the female screw hole 61h extend parallel to the axis O and coincide with each other. A female screw is formed in the female screw hole 61h. The second bolt 15 is passed through the through hole 39h from the other side in the direction of the axis O, and the tip of the second bolt 15 is screwed into the female screw of the through hole 61h. As a result, the hub attachment 61 is securely attached and fixed to the main body casing 39 by the second bolt 15.

  In FIG. 3, the second bolt 15 is not shown, and the through-hole 61 h is shown. Some of the plurality of through holes 61h, 61h... Are not provided with a female screw, but instead provided with a female screw in the through hole 39h, and a second bolt is passed through the through hole 61h from one side in the axis O direction. It may be screwed into a 39h female screw.

  Although the wall thickness of the main body casing 39 is substantially uniform, the wall thickness of the front portion 39f is not uniform, and the portion where the through hole 39h is formed is formed thicker than other portions. The thick portion 39g is arranged on the outer diameter side with respect to the output gear 37 described later.

  As shown in FIG. 3, the hub attachment 61 has a star shape that is rotationally symmetric about the axis O, and has a maximum outer diameter at the protrusion 61g and a minimum outer diameter at the protrusions 61g, 61g adjacent in the circumferential direction. . The maximum outer diameter of the hub attachment 61 is smaller than the inner diameter of the road wheel W, and is accommodated in the inner space area of the load wheel W together with the wheel hub bearing 11 (FIG. 4).

  A plurality of the first bolts 62 are arranged at equal intervals in the circumferential direction around the axis O. The same applies to the second bolt 15. The second bolt 15 is disposed on the outer diameter side of the first bolt 62 with respect to the axis O which is the center of the wheel hub bearing 11. In FIG. 3, the addendum circle of the output gear 37 is represented by a broken line. The first bolt 62 is arranged on the inner diameter side with respect to the addendum circle of the output gear 37, and overlaps with the output gear 37 when viewed in the direction of the axis O. On the other hand, the second bolt 15 is disposed on the outer diameter side of the addendum circle of the output gear 37.

  To add to the hub attachment 61, one end face in the axis O direction of the center region 61c abuts on the other end face in the axis O direction of the outer ring projection 13g. The other end face of the central region 61c in the direction of the axis O faces or contacts the front portion 39f. A female screw hole to be screwed with the first bolt 62 is formed in the central region 61c. Therefore, the central region 61c is connected to the outer ring projection 13g. As shown in FIG. 3, when viewed in the direction of the axis O, the position of the protrusion 61g and the position of the outer ring protrusion 13g overlap.

  The hub flange 12f of the inner race 12 and the outer race projection 13g are separated in the direction of the axis O, and the head of the first bolt 62 is arranged between the hub flange 12f and the outer race projection 13g. The brake disk BD attached and fixed to the hub flange 12f has a hat portion formed so as to be depressed outward in the vehicle width direction. That is, the brake disc BD includes an outer diameter region and an inner diameter region with the annular step BH as a boundary, the inner diameter region is arranged on one side in the axis O direction, and the outer diameter region is arranged on the other side in the axis O direction. The inner diameter region and the annular step BH constitute a hat portion. The hat section defines a cylindrical hollow area 90. Note that both end surfaces of the outer diameter region are friction surfaces.

  As shown in FIG. 3, the protrusion 12a of the hub flange 12f, the outer ring protrusion 13g, and the protrusion 61g of the hub attachment 61 are all located on the inner diameter side of the annular step BH of the brake disc BD. The head of the first bolt 62 is housed in the inner space area 90 of the hat.

  The outer peripheral surface 13b of the other region in the direction of the axis O of the outer ring 13 is fitted with the inner peripheral surface of the opening 39p. An annular groove is formed on the outer peripheral surface 13b, and the sealing material 65 is disposed in the annular groove. The sealing material 65 is, for example, an O-ring, and is in contact with the inner peripheral surface of the opening 39p on the entire circumference to seal a gap between the inner peripheral surface of the opening 39p and the outer peripheral surface 13b.

  As shown in FIG. 1, the motor unit 21 has a motor rotating shaft 22, a rotor 23, a stator 24, and a motor casing 29, and is arranged in this order from the axis M of the motor unit 21 to the outer diameter side. The motor section 21 is a radial gap motor of an inner rotor or outer stator type, but may be another type of electric motor. For example, although not shown, the motor unit 21 may be an axial gap motor. The motor casing 29 surrounds the outer periphery of the stator 24. One end of the motor casing 29 in the direction of the axis M is connected to the rear portion 39b of the main body casing 39. The other end in the direction of the axis M of the motor casing 29 is sealed with a plate-like motor casing cover 29v. The back surface portion 39b is a casing wall portion that covers the other end of the main casing 39 in the direction of the axis M (the direction of the axis O) of the reduction portion 31.

  The main body casing 39 and the motor casing 29 constitute a casing 10 that forms an outer shell of the in-wheel motor drive device 1. In the following description, when it is not necessary to distinguish the main body casing 39 and the motor casing 29, they are simply referred to as the casing 10.

  The stator 24 includes a cylindrical stator core 25 and a coil 26 wound around the stator core 25. The stator core 25 is formed by laminating ring-shaped steel plates in the direction of the axis M.

  Both ends of the motor rotation shaft 22 are rotatably supported by the back surface portion 39b of the main body casing 39 and the motor casing cover 29v of the motor unit 21 via rolling bearings 27 and 28. Most of the motor rotation shaft 22 except for one end 22 e in the axial direction is disposed in the motor casing 29. One end 22e in the axial direction is disposed inside the main body casing 39. That is, the motor rotation shaft 22 is housed in the casing 10 of the in-wheel motor driving device 1.

  An axis M that is the center of rotation of the motor rotation shaft 22 and the rotor 23 extends in parallel with the axis O of the wheel hub bearing 11. That is, the motor portion 21 is arranged to be offset from the axis O of the wheel hub bearing portion 11. For example, as shown in FIG. 2, the axis M of the motor unit is offset from the axis O in the vehicle front-rear direction, and specifically, is disposed forward of the axis O in the vehicle.

  The reduction unit 31 includes an input shaft 32 coaxially coupled to the motor rotation shaft 22 of the motor unit 21, an input gear 33 provided coaxially on an outer peripheral surface of the input shaft 32, a plurality of intermediate gears 34 and 36, An intermediate shaft 35 connected to the centers of the gears 34 and 36, an output shaft 38 connected to the inner ring 12 of the wheel hub bearing 11, an output gear 37 provided coaxially on the outer peripheral surface of the output shaft 38, It has a main body casing 39 that houses the gears and the rotating shaft. The main body casing 39 is also referred to as a reduction portion casing because it forms an outer shell of the reduction portion 31.

  The input gear 33 is a helical gear having external teeth. The input shaft 32 has a hollow structure, and one end 22e of the motor rotating shaft 22 in the axial direction is inserted into the hollow hole 32h, and is spline-fitted (including serrations, the same applies hereinafter) so as to be relatively unrotatable. The input shaft 32 is rotatably supported by the front portion 39f and the rear portion 39b of the main body casing 39 via rolling bearings 32a and 32b at both ends of the input gear 33.

  The axis N, which is the center of rotation of the intermediate shaft 35 of the reduction unit 31, extends parallel to the axis O. Both ends of the intermediate shaft 35 are rotatably supported by front and rear portions 39f and 39b of the main body casing 39 via rolling bearings 35a and 35b. A first intermediate gear 34 is coaxially provided at the other end of the intermediate shaft 35 in the direction of the axis N. A second intermediate gear 36 is coaxially provided in a central region of the intermediate shaft 35 in the direction of the axis N.

  In addition, a recess is formed on the other end surface of the first intermediate gear 34 in the direction of the axis N, and the bearing 35b is housed in the recess. Accordingly, the position of the bearing 35b in the direction of the axis N overlaps the position of the tooth surface of the first intermediate gear 34 in the direction of the axis N, and the length of the intermediate shaft 35 is reduced.

  The first intermediate gear 34 and the second intermediate gear 36 are helical gears having external teeth, and the diameter of the first intermediate gear 34 is larger than the diameter of the second intermediate gear 36. The large-diameter first intermediate gear 34 is arranged on the other side of the second intermediate gear 36 in the direction of the axis N, and meshes with the small-diameter input gear 33. The small-diameter second intermediate gear 36 is arranged on one side of the first intermediate gear 34 in the direction of the axis N, and meshes with the large-diameter output gear 37.

  The axis N of the intermediate shaft 35 is disposed higher than the axis O and the axis M as shown in FIG. The axis N of the intermediate shaft 35 is disposed forward of the axis O in the vehicle and rearward of the axis M in the vehicle. The speed reducer 31 is a three-axis parallel shaft gear reducer having axes O, N, and M that are arranged at intervals in the vehicle front-rear direction and extend in parallel with each other, and have a two-stage speed change.

  Returning to FIG. 1, the output gear 37 is a helical gear with external teeth, and is provided coaxially at the center of the axis O of the output shaft 38. Output shaft 38 extends along axis O. One end of the output shaft 38 in the direction of the axis O is inserted into the center hole of the inner race 12 and fitted so as not to rotate relatively. The center portion of the output shaft 38 in the direction of the axis O is rotatably supported by the front portion 39f of the main body casing 39 via a rolling bearing 38a on the outer diameter side with respect to the outer peripheral surface 13b shown in FIG. The other end of the output shaft 38 in the direction of the axis O is rotatably supported by a back surface portion 39b of the main body casing 39 via a rolling bearing 38b.

  As shown in FIG. 1, the reduction unit 31 is configured to mesh between a small-diameter drive gear and a large-diameter driven gear, that is, mesh between the input gear 33 and the first intermediate gear 34, mesh between the second intermediate gear 36 and the output gear 37, , The rotation of the input shaft 32 is reduced and transmitted to the output shaft 38. The rotation element from the input shaft 32 to the output shaft 38 of the reduction unit 31 forms a drive transmission path that transmits the rotation of the motor unit 21 to the inner ring 12.

  The main body casing 39 includes a cylindrical portion in addition to the front portion 39f and the rear portion 39b described above. The cylindrical portion covers the internal components of the speed reducer 31 so as to surround the axes O, N, and M extending parallel to each other. The plate-shaped front portion 39f covers the internal components of the reduction portion 31 from one side in the axial direction and is connected to one end of the cylindrical portion. The plate-shaped rear portion 39b covers the internal components of the speed reduction portion 31 from the other side in the axial direction, and is connected to the other end of the cylindrical portion. The rear portion 39b of the main body casing 39 is also a partition wall that is connected to the motor casing 29 and separates the internal space of the speed reduction unit 31 and the internal space of the motor unit 21. The motor casing 29 is supported by the main casing 39 and protrudes from the main casing 39 to the other axial side.

  The main body casing 39 partitions the internal space of the speed reduction unit 31 and accommodates all the rotating elements (rotation shafts and gears) of the speed reduction unit 31 in the internal space. As shown in FIG. 2, the lower part of the main body casing 39 is an oil storage part 41. The height position of the oil storage section 41 overlaps the height position of the lower part of the motor section 21. A lubricating oil that lubricates the motor unit 21 and the reduction unit 31 is stored in an oil storage unit 41 occupying a lower portion of the internal space of the main body casing 39.

  The input shaft 32, the intermediate shaft 35, and the output shaft 38 are supported at both ends by the above-described rolling bearing. These rolling bearings 32a, 35a, 38a, 32b, 35b, 38b are radial bearings.

  When electric power is supplied from the outside of the in-wheel motor drive device 1 to the above-described coil 26, the rotor 23 of the motor unit 21 rotates, and the rotation is output from the motor rotation shaft 22 to the reduction unit 31. The reduction unit 31 reduces the rotation input from the motor unit 21 to the input shaft 32 and outputs the rotation from the output shaft 38 to the wheel hub bearing unit 11. The inner ring 12 of the wheel hub bearing 11 rotates at the same rotational speed as the output shaft 38 and drives a wheel (road wheel W) (not shown) attached to and fixed to the inner ring 12.

  Here, the in-wheel motor drive device 1 includes a wheel speed detection unit that detects rotation of a wheel. Hereinafter, the mounting structure of the wheel speed detecting unit according to the present embodiment will be described in detail.

(About the mounting structure of the wheel speed detector)
With reference to FIG. 5 and FIG. 6, the mounting structure of wheel speed detecting section 50 in the present embodiment will be described. FIG. 5 is a front view of the in-wheel motor drive device 1 as viewed from the outside in the vehicle width direction. FIG. 6 is a cross-sectional view of the wheel hub bearing portion 11 and the peripheral portion of the in-wheel motor drive device 1 taken along a plane passing through the axis O.

  The wheel speed detection unit 50 includes a pulsar ring 51 attached to a rotating part, and a rotation sensor 54 attached to a fixed part and detecting rotation of the pulsar ring 51. The pulsar ring 51 is arranged in an inner space area 90 of the hat portion of the brake disc BD (hereinafter, referred to as “in the hat portion”). The rotation sensor 54 is fixed to, for example, the casing 10 so as to face the detected portion 52 of the pulsar ring 51 located in the hat portion. The pulsar ring 51 is formed of, for example, a magnetic material (thin steel plate), and the rotation sensor 54 is formed of, for example, a pickup coil.

  In the present embodiment, the pulsar ring 51 is mounted coaxially with the inner ring 12 of the wheel hub bearing 11. Specifically, the pulsar ring 51 is fixed to the hub flange 12f by a screw member 81.

  The pulsar ring 51 is formed of a plate-shaped member orthogonal to the axis O, and has an annular portion 51a centered on the axis O and a plurality of support portions 51b projecting radially inward from the inner peripheral edge of the annular portion 51a. And The detected portion 52 is provided on a surface facing the inside in the vehicle width direction of the annular portion 51a. The detected part 52 is formed by irregularities repeatedly provided in the circumferential direction. In the present embodiment, a concave portion of the detected portion 52 is constituted by the plurality of through holes 53 provided at a constant pitch in the annular portion 51a.

  The pulsar ring 51 has, for example, three support portions 51b, and each support portion 51b is fixed to the valley portion 12b of the hub flange 12f. The pulsar ring 51 can be reduced in weight as compared with a configuration in which the support portion 51b is fixed to each of the five valley portions 12b. Note that at least two support portions 51b may be provided. That is, the pulsar ring 51 may be fixed at at least two places among the plurality of valleys 12b of the hub flange 12f.

  The support portion 51b is formed in a V-shape so as to follow the shape of the valley portion 12b. A tongue portion 12t protruding radially outward is provided at a location for receiving the support portion 51b among the plurality of valley portions 12b of the hub flange 12f. The tongue 12t is provided at the bottom of the valley 12b. In FIG. 5, the tongue portion 12t is exaggerated.

  The thickness of the tongue 12t is less than the thickness of the hub flange 12f. The tongue portion 12t is formed so as to be separated from the brake disc BD and to be flush with the inner end face in the vehicle width direction of the hub flange 12f. In this case, a part (inner diameter side end) of the inner end surface in the vehicle width direction of the support portion 51b of the pulsar ring 51 is fixed in a state of being in contact with the outer end surface in the vehicle width direction of the tongue portion 12t.

  A through hole 51i is provided at the inner diameter end of the support portion 51b, and a female screw hole 12i is provided at the tongue portion 12t. A screw member 81 is passed through the through hole 51i of the support portion 51b and the female screw hole 12i of the tongue portion 12t from the outside in the vehicle width direction, and the shaft of the screw member 81 is screwed into the female screw hole 12i of the tongue portion 12t. In the attached state, it is desirable that the pulsar ring 51 is disposed away from the inner end surface in the vehicle width direction (the bottom surface of the hat portion) of the inner diameter region of the brake disc BD. It is desirable that the head of the screw member 81 is also located away from the inner end surface in the vehicle width direction (the bottom surface of the hat portion) of the inner diameter region of the brake disc BD.

  The rotation sensor 54 is attached to the casing 10. Specifically, the rotation sensor 54 is attached to a portion of the casing 10 facing the inner diameter region (hat portion) of the brake disc BD, for example, via a holding member (stay) 55. 7 and 8 show a configuration example of the holding member 55. FIG.

  The holding member 55 includes a mounting portion 56 extending in the radial direction, and a holding portion 57 extending obliquely upward from the upper end of the mounting portion 56 outward in the vehicle width direction. The holding portion 57 is inclined so that the angle with the attachment portion 56 is an obtuse angle. The mounting portion 56 is provided with a through hole 56 a for inserting the screw member 82. The holding member 55 is fixed to the casing 10 by screwing the screw member 82 inserted into the through hole 56a into a female screw hole formed in the wall portion (front portion 39f) of the casing 10.

  The holding portion 57 is provided with a through hole 57 a for fitting the main body of the rotation sensor 54 and a through hole 57 b for inserting the screw member 83 that has passed through the fixing piece 54 b of the rotation sensor 54. An internal thread (not shown) is formed on the inner wall of the through hole 57b. The screw member 83 is screwed into the through hole 57b with the fixing piece 54b of the rotation sensor 54 sandwiched between the head and the holding portion 57. Thereby, the rotation sensor 54 is held by the holding member 55 in a state where the posture and the orientation are fixed.

  The rotation sensor 54 is fixed such that the detection surface 54 a located at the tip thereof faces the detected portion 52 of the pulsar ring 51. When the pulsar ring 51 rotates, the rotation sensor 54 outputs, as a voltage, an electromotive force that changes according to the unevenness of the detected portion 52 of the pulsar ring 51. The detection signal of the rotation sensor 54 is transmitted to a control device provided on the vehicle body side.

  As described above, since the pulsar ring 51 is disposed in the hat portion of the brake disc BD, the wheel speed detection unit 50 can be mounted without increasing the length of the in-wheel motor drive device 1 in the axle direction. Specifically, since the pulsar ring 51 is arranged within the thickness range of the hub flange 12f, not only the pulsar ring 51 but also at least the distal end portion of the rotation sensor 54 can be arranged in the hat portion of the brake disc BD.

  Further, since the pulsar ring 51 is attached to the valley portion 12b of the hub flange by the support portion 51b, it is possible to suppress an increase in the diameter of the pulsar ring 51. In the present embodiment, when viewed in the direction of the axis O, the entire annular portion 51a (detected portion 52) of the pulsar ring 51 or at least the inner diameter side portion thereof overlaps the hub attachment 61 (FIG. 5).

  In addition, since the wheel speed detection unit 50 is disposed in the hat portion of the brake disc BD, detection failure due to adhesion of mud, snow, brake dust, and the like can be prevented.

  Further, in the present embodiment, since the pulsar ring 51 is attached to the hub flange 12f of the wheel hub bearing 11, the detection surface 52 of the detected portion 52 of the pulsar ring 51 and the detection surface of the rotation sensor 54 with the brake disc BD removed. It is possible to confirm the distance D1 from the position 54a, that is, the air gap (FIG. 6). Therefore, the adjustment of the interval D1 can be performed accurately. As a result, the rotation speed of the wheel can be accurately detected by the wheel speed detection unit 50. When the pulsar ring is attached to the brake disc BD instead of the hub flange 12f, a jig is required for adjusting the air gap. However, such a jig can be eliminated. Therefore, according to the present embodiment, the number of steps for attaching and detaching the jig can be reduced.

  Further, in the present embodiment, the rotation sensor 54 is attached to the casing 10 using the holding member 55 in a state where the rotation sensor 54 is inclined. In this case, since the detected portion 52 of the pulsar ring 51 does not need to be extended to the outside of the casing 10, the diameter of the pulsar ring 51 can be reduced. Thereby, the distance from the support portion 51b of the pulsar ring 51 to the outer diameter portion is shortened, and the peripheral speed of the outer diameter portion can be reduced, so that rigidity can be ensured even when the plate thickness of the pulsar ring 51 is reduced. . Further, since the diameter of the pulsar ring 51 can be reduced, processing with a small press machine becomes possible, which can contribute to cost reduction.

  In addition, since the diameter of the pulsar ring 51 can be reduced, it is not necessary to expand the hat portion of the brake disc BD to a size larger than the required braking performance. Thus, the diameter of the brake disc BD and the road wheel W of the wheel can be reduced, so that the unsprung weight can be reduced, and the riding comfort and running performance of the vehicle can be improved.

  In the present embodiment, the configuration in which the in-wheel motor drive device 1 includes the hub attachment 61 has been described as an example. However, as an unillustrated embodiment, the outer ring having no hub attachment 61 and having a relatively large diameter is provided in the casing 10. It may be fixed to. In this case, when viewed in the direction of the axis O, the entire annular portion 51a (detected portion 52) of the pulsar ring 51, or at least the inner diameter side portion thereof, may be arranged so as to overlap the outer ring.

(Modification 1)
In the present embodiment, the wheel hub bearing 11 of the inner ring rotation type is shown as an example. However, as shown in FIGS. 9 and 10, the pulsar ring 51 may be attached to the wheel hub bearing of the outer ring rotation type. Good. 9 and 10 show an example in which the wheel speed detection unit 50 is mounted on the in-wheel motor driving device 1A including the outer wheel rotation type wheel hub bearing 11A.

  The wheel hub bearing portion 11A includes an outer ring 112 serving as a wheel hub connected to a wheel, an inner fixed member 113 passed through a center hole of the outer ring 112, and a plurality of rings arranged in an annular gap between the outer ring 112 and the inner fixed member 113. Rolling elements 114. A hub flange 112f is formed at one end of the outer race 112 in the direction of the axis O. The outer ring 112 is connected to the brake disc BD and the wheel by the hub flange 112f, and rotates integrally with the wheel. The hub flange 112f also includes a plurality of protrusions 112a that protrude toward the outer diameter side at intervals in the circumferential direction, and a plurality of valleys 112b formed between the protrusions 112a that are adjacent in the circumferential direction. .

  Also in this example, at least two of the plurality of valleys 112b of the hub flange 112f are provided with tongues 112t protruding radially outward. The pulsar ring 51 is fixed to the tongue 112t by the screw member 81 via the support 51b.

(Modification 2)
In order to prevent malfunction of the rotation sensor 54, a heat shield may be provided between the brake disc BD and the rotation sensor 54. FIG. 11 shows an example in which the heat shield plate 70 is fixed to the casing 10 of the in-wheel motor driving device 1A shown in FIG.

  The heat shield plate 70 is configured by an arc-shaped member centered on the axis O. The heat shield plate 70 is located radially outside of the pulsar ring 51, and is fixed to the front wall of the casing 10 by a plurality of screw members 84. The heat shield plate 70 is disposed so as to cover a portion of the front wall portion of the casing 10 facing the outer diameter region of the brake disc BD and a portion protruding from the casing 10 and in which the rotation sensor 54 is disposed. Is done.

  The outer diameter side edge of the heat shield plate 70 is located outside the outer circumference circle of the outer diameter region of the brake disc BD, and the inner diameter side edge of the heat shield plate 70 is located outside the inner circumference circle of the outer diameter region of the brake disc BD. Is also located inside. It is desirable that a portion 71 of the inner diameter side edge of the heat shield plate 70 that overlaps the position where the rotation sensor 54 is disposed is bent outward in the vehicle width direction so as to face the annular step BH of the brake disc BD. The entire outer edge 72 of the heat shield plate 70 may be bent outward in the vehicle width direction. The schematic cross-sectional view of FIG. 12 shows a cross-sectional shape of the heat shield plate 70.

<Embodiment 2>
Next, with reference to FIGS. 13 and 14, a description will be given of a wheel speed detection unit 50A mounted on the in-wheel motor drive device 1B according to Embodiment 2 of the present invention. In the first embodiment, the pulsar ring 51 is fixed to the hub flange 12f by the screw member 81, whereas in the present embodiment, the pulsar ring 151 is press-fitted and fixed to the hub flange 212f.

  The wheel hub bearing 11B in the present embodiment is of an outer ring rotating type like the wheel hub bearing 11A shown in the first modification of the first embodiment, but the wheel hub bearing shown in the first embodiment is used. The inner ring rotation type as in the part 11 may be used. The outer ring 212 of the wheel hub bearing 11B has a hub flange 212f having a uniform outer diameter (not a petal shape).

  The pulsar ring 151 in the present embodiment includes a cylindrical portion 51c instead of the above-described support portion 51b. That is, the pulsar ring 151 includes the annular portion 51a arranged orthogonal to the axis O and the cylindrical portion 51c fitted to the hub flange 212f. It is desirable that the cylindrical portion 51c is arranged within the range of the thickness dimension of the hub flange 212f. In the present embodiment, the inner edge of the cylindrical portion 51c in the vehicle width direction and the inner edge of the annular portion 51a having the detected portion 52 are integrally connected.

  As described above, when the pulsar ring 151 is fixed while being pressed into the hub flange 212f, the pulsar ring 151 is attached to the hub flange 212f without processing the hub flange 212f, for example, by providing the tongue portion 12t described above. be able to. Further, since the screw member is not required, the work of attaching the pulsar ring 151 can be simplified.

(Modification)
In the present embodiment, the detected portion 52 of the pulsar ring 151 is provided on the annular portion 51a arranged orthogonal to the axis O as in the first embodiment. The detected portion 52 may be provided on the cylindrical portion itself. 15 and 16 show configuration examples of a wheel speed detection unit 50B according to a modification of the second embodiment.

  The pulsar ring 251 of the wheel speed detecting unit 50B is arranged coaxially with the wheel hub bearing 11B, and is formed of a cylindrical portion that fits with the hub flange 212f. That is, the pulsar ring 251 is formed in a cylindrical shape. In this case, on the outer peripheral surface of the pulsar ring 251, there is provided a detection target 52 </ b> A having irregularities repeatedly formed in the circumferential direction. In the present modification, the rotation sensor 54 is fixed such that the detection surface 54a at the distal end faces radially inward.

  The axial length of the pulsar ring 251 is longer than the thickness of the hub flange 212f, and the pulsar ring 251 may protrude from the hub flange 212f inward in the vehicle width direction. As a result, the rear end portion of the rotation sensor 54 can be disposed outside the hat portion of the brake disc BD, so that the diameter of the brake disc BD can be reduced as compared with a configuration in which the entire rotation sensor 54 is disposed inside the hat portion of the brake disc BD. Can be.

  Note that the detected portion 52A of the pulsar ring 251 of the present modification may be combined with the support portion 51b of the pulsar ring 51 of the first embodiment. That is, the pulsar ring having the cylindrical portion provided with the detected portion 52A on the outer peripheral surface may be fixed to the hub flange by the screw member via the support portion extending radially inward from the cylindrical portion.

  Further, the structure in which the pulsar ring is press-fitted and fixed to the hub flange as in the present embodiment can be applied to a petal-shaped hub flange as described in the first embodiment. As an example, FIG. 17 shows a state in which a cylindrical pulsar ring 251 is press-fitted and fixed to a petal-shaped hub flange 112f included in the wheel hub bearing 11A shown in the first modification of the first embodiment. In this case, the inner peripheral surface of the pulsar ring 251 makes surface contact only at the protruding portion 112a of the hub flange 112f.

<Other embodiments>
In each of the above embodiments, the rotation sensor 54 is fixed to the casing 10, but the rotation sensor 54 may be attached to a fixed portion of the wheel hub bearing that does not rotate. Alternatively, the rotation sensor 54 may be attached to a hub supporting member that supports the wheel hub bearing. For example, in wheel hub bearing 11 of the first embodiment, rotation sensor 54 may be fixed to outer ring 13 or hub attachment 61.

  Further, the rotation sensor 54 is attached to the fixed portion of the in-wheel motor drive device via the holding member 55. However, the rotation sensor 54 may be directly attached to the fixed portion of the in-wheel motor drive device without passing through the holding member 55. Good.

  Further, in each embodiment, the wheel speed detection unit adopting the passive system has been described, but the active system may be employed. In that case, a known magnetic encoder, for example, may be employed as the detected part of the pulsar ring. The magnetic encoder is an annular magnet in which an N pole and an S pole are repeatedly arranged in a circumferential direction. In this case, the rotation sensor 54 reads the strength of the magnetism accompanying the rotation of the magnetic encoder.

  In the above description, the brake disk BD is shown as the disk-type brake rotor, but a drum-type brake rotor may be used. Also, the example in which the reduction unit 31 is a parallel three-axis gear reducer having axes O, R, and M extending parallel to each other has been described, but the configuration of the reduction unit 31 is not limited. It may be applied to a motor or a cycloidal reducer.

  The embodiments disclosed this time are to be considered in all respects as illustrative and not restrictive. The scope of the present invention is defined by the terms of the claims, rather than the description above, and is intended to include any modifications within the scope and meaning equivalent to the terms of the claims.

  1, 1A, 1B in-wheel motor drive device, 10 casing, 11, 11A, 11B wheel hub bearing portion, 12f, 112f, 212f hub flange, 21 motor portion, 31 reduction portion, 50, 50A, 50B wheel speed detection portion, 51, 151, 251 pulsar ring, 52, 52A detected part, 54 rotation sensor, 55 holding member, 70 heat shield plate, BD brake disc.

Claims (7)

A motor drive device for a vehicle arranged inside a wheel,
A wheel hub bearing portion including a brake rotor having a hat portion formed to be recessed outward in the vehicle width direction and a rotating wheel coaxially coupled to the wheel;
A wheel speed detection unit that detects rotation of the wheel,
The wheel speed detector,
A pulsar ring having a detected portion disposed in a hat portion of the brake rotor, and being mounted coaxially with the rotating wheel of the wheel hub bearing portion;
A rotation sensor attached to a fixed portion so as to face the detected portion of the pulsar ring. The rotating wheel of the wheel hub bearing has a hub flange projecting radially outward,
The in-wheel motor drive device according to claim 1, wherein the pulsar ring is fixed to the hub flange by a screw member. The hub flange includes a plurality of protrusions arranged at intervals in the circumferential direction, and a plurality of valleys located between the protrusions,
The in-wheel motor drive device according to claim 2, wherein the pulsar ring is fixed at at least two of the plurality of valleys of the hub flange. The rotating wheel of the wheel hub bearing has a hub flange projecting radially outward,
The in-wheel motor drive device according to claim 1, wherein the pulsar ring is fixed while being pressed into the hub flange. A motor unit including a motor rotating shaft that drives the rotating wheel of the wheel hub bearing unit;
And a casing that houses the motor unit.
The in-wheel motor according to any one of claims 1 to 4, wherein the rotation sensor is attached to the casing, a fixed portion of the wheel hub bearing, or a hub supporting member that supports the wheel hub bearing. Drive.   The in-wheel motor drive device according to claim 1, wherein the rotation sensor is held by a holding member fixed to the fixed portion.   The in-wheel motor drive device according to any one of claims 1 to 6, further comprising a heat shield plate disposed between the rotation sensor and the brake rotor.

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