JP5233403B2 - Rotating electric machine and electric power steering apparatus using the same - Google Patents

Description

  The present invention relates to a rotating electrical machine including a stator around which coils of a plurality of phases are wound, a rotor disposed on the inner periphery of the stator, a housing body incorporating the stator, and a power feeding connector disposed in the vicinity of the housing body, An object of the present invention is to provide an electric power steering apparatus using the same.

  In general, an electric power steering device is connected to a steering assist mechanism that transmits a steering assist force to an output shaft of a steering shaft. The steering assist mechanism is connected to a reduction gear connected to the output shaft and to the reduction gear. The electric motor (rotating electric machine) that generates the steering assist force is provided, and the electric motor is driven and controlled based on a torque detection signal detected by a torque sensor provided in the steering system.

In the electric motor, a cylindrical stator around which a coil is wound, a rotor having a magnetic pole and an output shaft facing the stator, and an angle detector that detects a rotation angle of the rotor are arranged in a motor case. A power feeding unit is provided for electrically connecting the external power source and the stator coil.
For example, techniques disclosed in Patent Documents 1 to 3 are known as a power feeding unit of a conventional electric motor.

  In the technique of Patent Document 1, a power harness is inserted from the outside of the motor into a through hole provided in the motor case, and one end of the power harness extending into the motor case is electrically connected to a terminal block provided in the stator coil. Then, the power harness that has passed through the through hole is surrounded by a grommet, and the outer periphery of the grommet is covered with a metal cover so that the power harness is drawn out from the motor case.

Further, the technology of Patent Documents 2 and 3 is such that a power supply connector is fixed to the outer periphery of the motor case, and a bus bar arranged in the motor case is connected to a connection terminal extending from the power supply connector into the motor case (Patent Document 2). In this case, the power supply unit has a structure in which the brush holder is integrated and the power harness does not exist in the motor case.
JP 2007-82373 A JP 2002-291205 A JP 2008-29120 A

  However, in the electric power feeding structure of the electric motor of Patent Document 1, when the electric motor is a brushless motor provided with a plurality of coils, the electric motor is electrically connected to the ends of the plurality of power harnesses drawn from the motor case to the outside. The connector to be connected must be provided on the external power supply side (for example, the power supply unit integrated with the housing of the reduction gear), and the structure of the power feeding unit with an increased number of connector parts increases, which increases the manufacturing cost of the electric power steering device There is a risk.

  On the other hand, the techniques of Patent Documents 2 and 3 are not provided with a connector on the external power supply side, and become a simple power feeding structure that does not pull out the power harness from the motor case, but matched to the shape of the motor case and the structure inside the motor case. A unique power connector must be developed, and power connector components cannot be shared. Further, the structure for supporting the power supply connector on the motor case may be complicated. Therefore, the techniques of Patent Documents 2 and 3 may increase the manufacturing cost of the electric motor.

  Accordingly, the present invention has been made paying attention to the above-mentioned unsolved problems of the conventional example, and can be arranged to support and arrange a power supply connector having a general structure in the vicinity of the housing body, and in a simple manner. An object of the present invention is to provide a rotating electrical machine that can reduce the manufacturing cost by adopting a power feeding connecting portion having a simple structure, and an electric power steering device using the rotating electrical machine.

In order to achieve the above object, a rotating electrical machine according to claim 1 detects a cylindrical stator around which coils of a plurality of phases are wound, a rotor disposed on the inner periphery of the stator, and a rotation angle of the rotor. A rotation angle detector, a housing main body including the stator and the rotation angle detector, a power supply connector disposed in the vicinity of the housing main body, and the power supply connector and the coils of the plurality of phases are electrically connected. A power supply connection portion, and a connector support portion disposed between an outer periphery of the housing main body and the power supply connector, and supporting the power supply connector on the housing main body, wherein the power supply connection portion is provided on the housing main body. One end of the harness that is disposed through the through hole and is located inside the housing body is electrically connected to the coils of the plurality of phases. Wherein a short a plurality of power harness harness other end is electrically connected to the power feeding connector located outside of the housing body is mounted in a through hole provided in the housing body, the plurality of A grommet through which each of the power harnesses is inserted, and a holding plate for pressing the grommet against the housing body, and the connector support portion protrudes from the holding plate and the power supply connector is disposed. A bracket portion extending to a position where the power supply connector is fixed to the bracket portion, and the housing is arranged so that the bracket portion and the power supply connector extend in the direction of the rotation axis of the rotor. It arrange | positions along the outer periphery of a main body.

According to a second aspect of the present invention, there is provided a rotating electrical machine having a cylindrical stator around which coils of a plurality of phases are wound, a rotor disposed on the inner periphery of the stator, and a rotation angle detector for detecting a rotation angle of the rotor. A housing body incorporating the stator and the rotation angle detector, a power feeding connector disposed in the vicinity of the housing body, a power feeding connecting portion for electrically connecting the power feeding connector and the coils of the plurality of phases, A connector supporting portion disposed between an outer periphery of the housing main body and the power feeding connector, and supporting the power feeding connector on the housing main body, the power feeding connecting portion passing through a through hole provided in the housing main body. One end of the harness disposed and located inside the housing body is electrically connected to the coils of a plurality of phases, respectively, and the housing body The other end of the harness located outside has a plurality of short power harnesses that are electrically connected to the power supply connector, and the housing body has one end opened and the other end closed, at least the stator And a flange that closes the opening of the case on the opening side of the case, and the connector support portion protrudes from the opening edge of the case and the power supply connector is disposed. A bracket portion extending to a position where the power supply connector is fixed to the bracket portion, and the housing is arranged so that the bracket portion and the power supply connector extend in the direction of the rotation axis of the rotor. It arrange | positions along the outer periphery of a main body.

According to a third aspect of the present invention, in the rotating electrical machine according to the first or second aspect of the present invention, the rotating electric machine includes a cover portion that branches from the bracket portion and surrounds the plurality of power harnesses.

An electric power steering apparatus according to a fourth aspect uses the rotating electrical machine according to any one of the first to third aspects as a motor that generates a steering assist force in the steering mechanism.

According to the rotating electrical machine according to the present invention, a dedicated connector that is directly fixed to the housing body as in the conventional structure is not necessary, and the connector support portion is simply disposed between the power feeding connector of the general structure and the housing body. Since the power feeding connector can be reliably supported on the housing body, the manufacturing cost of the rotating electrical machine can be reduced.
Further, the rotating electrical machine of the present invention has a power supply connection portion for electrically connecting a power supply connector and a plurality of coils passing through a through hole provided in the housing body, and one end of the harness located inside the housing body As a simple structure having a plurality of short power harnesses, each of which is electrically connected to the coils of the plurality of phases and the other end of the harness located outside the housing body is electrically connected to the power supply connector Therefore, the manufacturing cost of the rotating electrical machine can be further reduced.

  In addition, the electric power steering apparatus using the rotating electric machine having the above-described configuration can also reduce the manufacturing cost.

Hereinafter, the best mode for carrying out the present invention (hereinafter referred to as an embodiment) will be described in detail with reference to the drawings.
FIG. 1 is an overall configuration diagram showing an embodiment in which the present invention is applied to an electric power steering apparatus. In the figure, reference numeral 1 denotes an electric power steering apparatus. The electric power steering apparatus 1 is a driver. Is provided with a steering mechanism 2 for steering.
The steering mechanism 2 includes a steering shaft 4 having an input shaft 4a and an output shaft 4b through which a steering force applied from a driver is transmitted to the steering wheel 3, and the steering shaft 4 is one end of the input shaft 4a. Is connected to the steering wheel 3, and the other end is connected to one end of the output shaft 4b via a steering torque sensor 5 as steering torque detecting means.

  The steering force transmitted to the output shaft 4 b is transmitted to the lower shaft 7 via the universal joint 6 and further transmitted to the pinion shaft 9 via the universal joint 8. The steering force transmitted to the pinion shaft 9 is transmitted to the tie rod 11 via the steering gear 10 to steer a steered wheel (not shown). Here, the steering gear 10 is configured in a rack and pinion type having a pinion 10a connected to the pinion shaft 9 and a rack 10b meshing with the pinion 10a, and the rotational motion transmitted to the pinion 10a is linearly moved by the rack 10b. It has been converted to movement.

A steering assist mechanism 12 that transmits a steering assist force to the output shaft 4b is connected to the output shaft 4b of the steering shaft 4. The steering assist mechanism 12 includes a reduction gear 13 connected to the output shaft 4 b and a brushless motor 14 that generates a steering assist force connected to the reduction gear 13.
The brushless motor 14 receives the steering torque applied to the steering wheel 3 detected by the steering torque sensor 5 and transmitted to the input shaft 4a, and the vehicle speed detection value output from the vehicle speed sensor 41 that detects the vehicle speed. Is controlled by the control device 42.

  The control device 42 refers to a control map that stores the relationship between the steering torque and the steering assist command value using the vehicle speed detection value as a parameter, calculates the steering assist command value, and calculates the calculated steering assist command value and the brushless motor 14. The motor current command value is calculated by performing feedback control based on the motor current flowing through the motor, and the calculated motor current command value is supplied to the motor drive circuit 43 configured by an inverter circuit. A motor drive current is formed based on a current command value and an angle detection signal from a resolver 20 that detects a rotor rotation angle of the brushless motor 14 to be described later, and this motor drive current is supplied to the brushless motor 14 to thereby generate a brushless motor. 14, the steering assist force according to the steering assist command value is generated.

(Brushless motor of the first embodiment)
2 and 3 show the brushless motor 14 of the first embodiment.
As shown in FIG. 2, the brushless motor 14 of the present embodiment includes a motor case 15 formed in a substantially cylindrical shape with one end opened and the other end closed, and the motor case 15 on the opening side of the motor case 15. Flange 16 coupled so as to close the opening, a substantially annular stator 17 attached to the inner wall 15a of the motor case 15, a rotor 18 disposed on the inner peripheral side of the stator 17, and a rotation angle of the rotor 18 , A power harness 34 of a motor connecting portion 22 (to be described later) that electrically connects a plurality of coils 29 (to be described later) of the connector 17 and the stator 17 disposed in the vicinity of the flange 16, and an electric power to the power harness 34. And a support spacer 36 for supporting the connected connector 35 on the flange 16.

At the other end of the motor case 15, a fitting portion 15b for fitting the rear bearing 21b is formed. The rear bearing 21 b rotatably supports one axial end side of the shaft 19 of the rotor 18.
The flange 16 is provided with a bearing fitting hole 23 for fitting the front bearing 21a on the inner diameter side, and a plurality of bolt through holes 24 on the outer diameter side. The front bearing 21 a rotatably supports the other axial end side of the shaft 19.

  A cylindrical coupling portion 25 that protrudes in the axial direction and is coupled to the opening periphery of the motor case 15 is integrally formed on one end face of the flange 16 facing the axial direction. A harness outlet 26 that protrudes outward in the direction is provided. The harness outlet 26 is formed with a motor internal space S defined by the flange 16 and the motor case 15 and a grommet mounting hole 26a communicating with the outside of the motor. Further, connecting bolts (not shown) are inserted into the plurality of bolt through holes 24 provided on the outer diameter side of the flange 16, and these connecting bolts are inserted into a gear housing (not shown) in which the components of the reduction gear 13 are built. The brushless motor 14 is integrated with the reduction gear 13 by screwing.

  The stator 17 has a stator core 27 in which metal core plates are laminated, and a three-phase coil 29 is wound on the inner peripheral side of the stator core 27 via an insulator 28. The terminal of each phase coil 29 is electrically connected to the bus bar (not shown) of the terminal block 30 fixed to one end of the stator core 27 which is the opening side of the motor case 15 by fusing or TIG welding. .

  The rotor 18 has a shaft 19 rotatably supported at both ends by a front bearing 21a and a rear bearing 21b, a rotor core 31a press-fitted into the outer periphery of the shaft 19, or integrally formed with the shaft, and an outer periphery of the rotor core 31a. And the like, a circular rotor cover 32 that is attached to the outer peripheral surface of the magnet 31b and covers the magnet 31b, and a resolver rotor 20r that constitutes the resolver 20 that is fixed to the outer periphery of one end of the shaft 19. ing. The magnet 31b has a plurality of magnetic poles arranged in the circumferential direction of the shaft 19, and the resolver rotor 20r is composed of an annular permanent magnet in which the plurality of magnetic poles extend in the circumferential direction.

The resolver 20 is composed of the resolver rotor 20r described above and an annular resolver stator 20s surrounding the outer periphery of the resolver rotor 20r. It is supported by a fixed resolver holder 33.
The motor connection portion 22 is inserted into the grommet 38 made of an elastic member attached to the grommet attachment hole 26 a of the harness outlet 26, and one end portion extending into the internal space S is inserted into the insertion hole of the grommet 38. Three short power harnesses 34 electrically connected to the terminal block 30 of the coil 29 and having the other end extending outside the motor electrically connected to the metal terminal of the connector 35, and a harness outlet 26, a holding plate 39 fixed to the end face of the connector 26 with a screw 39a while the power harness 34 is inserted.

Core wire portions are exposed at one end side of the three power harnesses 34 extending in the internal space S, and bus bars 37 are integrated with these core wire portions, and the coils 29 of the respective phases of the corresponding stator 17 are integrated. Each terminal bar 30 is electrically connected to the bus bar by welding or screwing.
The grommet 38 mounted in the grommet mounting hole 26a absorbs vibration input from the harness outlet 26 side, prevents vibration transmission to the power harness 34, and keeps the internal space S airtight.

The holding plate 39 has a function of pressing the grommet 38 in the grommet mounting hole 26a toward the flange 16 side.
The connector 35 includes a terminal metal (not shown) to which the other ends of the three power harnesses 34 are connected, and a box-shaped connector housing 40 made of a synthetic resin that accommodates these terminal metals. It is extended and arranged in the direction which intersects perpendicularly. The connector 35 is detachably connected to a harness-side connector (not shown) provided at the tip of the power harness drawn from the motor drive circuit 43.

  The support spacer 36 is a box-shaped member that is interposed between the harness outlet 26 and the connector 35 and supports the connector 35 to the cylindrical coupling portion 25 of the flange 16. As shown in FIG. The first support surface 36a that abuts on the surface facing the connector 35 and a part of the side surface of the harness outlet 26 in a surface contact state, and the surface that faces the harness outlet 26 of the connector housing 40 abuts on the surface. And a second support surface 36b.

The support spacer 36 is composed of a first block 36c and a second block 36d that are divided in half by a portion through which the three power harnesses 34 pass, and the first block 36c and the second block 36d abut against each other. It is integrated by joining the parts.
The support spacer 36 has the first support surface 36 a and the second support surface 36 b in contact with the holding plate 39, a part of the side surface of the harness outlet 26 and the surface of the connector housing 40 in a surface contact state. Is supported by the cylindrical coupling portion 25 of the flange 16.

Note that the structure of the harness outlet 26 of the support spacer 36 is a structure in which a convex portion is fitted and locked in a recess such as a groove provided in the harness outlet 26 and is divided into two parts in the harness outlet. It may be a structure that is fitted and locked in the provided recess, or a shape that is sandwiched between the opening of the motor case 15 and the cylindrical coupling portion 25 of the flange 16.
Here, reference numeral 44 in FIG. 1 is a sensor harness that outputs an angle detection signal detected by the resolver 20 to the motor drive circuit 43.

Next, the operation of the electric power steering apparatus 1 according to this embodiment will be described.
Assuming that the vehicle is now stopped, in this state, when the steering wheel 3 is turned to the right (or left), the steering torque applied to the steering wheel 3 is the steering torque. The detected steering torque detected by the sensor 5 is input to the control device 42, and the zero vehicle speed detection value detected by the vehicle speed sensor 41 is input to the control device 42.

  The control device 42 refers to the control map based on the steering torque and the vehicle speed detection value, calculates a relatively large steering assist command value, and performs feedback control based on the deviation between the steering assist command value and the motor current detection value. The motor current command value is calculated by performing this operation, and the motor current command value is output to the motor drive circuit 43, whereby the motor drive current based on the angle detection signal detected by the resolver 20 is obtained by the motor drive circuit 43. In addition, a power harness drawn from the motor drive circuit 43, a connector connected to the power harness, and a motor connection portion 22 having a connector 35 connected to the connector are fed to the coils 29 of the plurality of phases of the stator 17 of the brushless motor 14. Is done.

  When a motor drive current is supplied to the multiple-phase coils 29 of the stator 17, the rotor 18 is rotationally driven by the generation of the rotating magnetic field of the stator 17 to generate a steering assist force. This steering assist force is transmitted via the shaft 19. When transmitted to the reduction gear 13, the reduction gear 13 can apply a large steering assist torque to the output shaft 4 b of the steering shaft 4 in the same direction as the rotation direction of the steering wheel 3, so that the steering wheel 3 can be lightly steered. it can.

When the vehicle is driven from this state, the calculated steering assist command value becomes a small value even if the steering torque is the same as the vehicle speed detection value increases, and the brushless motor 14 is driven to rotate accordingly. The steering assist force generated by the brushless motor 14 is smaller than that at the time of stationary, and the optimum steering assist force corresponding to the vehicle speed is generated.
Next, the effects of the brushless motor 14 of the first embodiment and the electric power steering apparatus 1 including the brushless motor 14 will be described.

In the present embodiment, a connector 35 is disposed in the vicinity of the harness outlet 26 of the brushless motor 14, and this connector 35 is supported by the cylindrical coupling portion 25 of the flange 16 via a support spacer 36. The spacer 36 is disposed in surface contact with the holding plate 39 and the connector housing 40 disposed at the harness outlet 26.
Therefore, this embodiment eliminates the need for a dedicated connector that is directly fixed to the motor case as in the conventional structure, and merely disposes the support spacer 36 between the connector 35 and the harness outlet 26 having a general structure. Since the connector 35 can be reliably supported by the cylindrical coupling portion 25 of the flange 16, the manufacturing cost of the brushless motor 14 can be reduced.

  Further, the metal terminal in the connector housing 40 of the connector 35 and the terminal block 30 of the multi-phase coil 29 of the stator 17 disposed in the motor case 15 are electrically connected via the short power harness 34 of the motor connection portion 22. Therefore, the manufacturing cost of the brushless motor 14 can be further reduced as compared with the conventional structure in which a dedicated bus bar is disposed in the motor case.

Further, since the support spacer 36 interposed between the cylindrical coupling portion 25 and the connector 35 is disposed in a state of covering all three power harnesses 34, for example, a pinion type electric power steering When applied to the apparatus, it can serve as a covering protection that prevents the stepping stones from hitting the power harness 34.
Moreover, since the electric power steering apparatus 1 including the brushless motor 14 according to the present embodiment can set the harness length shorter than a conventional structure in which a plurality of power harnesses are pulled out from the motor. In addition, the manufacturing cost of the electric power steering apparatus 1 can be reduced.

(Brushless motor of the second embodiment)
Next, FIG. 4 shows the brushless motor 14 of the second embodiment. The same components as those shown in FIGS. 2 and 3 are denoted by the same reference numerals, and the description thereof is omitted.
In the brushless motor 14 of the present embodiment, three substantially annular support spacers 45 a, 45 b, 45 c that surround each of the three power harnesses 34 are interposed between the harness outlet 26 and the connector 35.
These three support spacers 45a, 45b, and 45c are respectively provided with first support surfaces 45a1, 45b1, and 45c1 that are in surface contact with the surface of the holding plate 39 that faces the connector 35, and the harness outlet 26 of the connector housing 40. The second support surfaces 45a2, 45b2, 45c2 are in contact with the surfaces facing the first and second surfaces 45a2, 45b2, 45c2, and the second support surfaces 45a1, 45b1, 45c1 and the second support surfaces 45a2, 45b2, 45c2 By contacting the surface of the connector housing 40 in a surface contact state, the connector 35 is supported by the cylindrical coupling portion 25 of the flange 16.

According to the present embodiment, the connector 35 is formed in the cylindrical shape of the flange 16 only by arranging the three substantially annular support spacers 45 a, 45 b, 45 c between the connector 35 having a general structure and the harness outlet 26. Since it can support to the coupling | bond part 25 reliably, the reduction of the manufacturing cost of the brushless motor 14 can be aimed at.
Similarly to the first embodiment, the metal terminal in the connector housing 40 of the connector 35 and the terminal block 30 of the multi-phase coil 29 of the stator 17 arranged in the motor case 15 are short in length of the motor connecting portion 22. Since the power harness 34 is electrically connected, the manufacturing cost of the brushless motor 14 can be further reduced.

Further, the three support spacers 45a, 45b, 45c interposed between the cylindrical coupling portion 25 and the connector 35 are arranged in a state of covering each of the three power harnesses 34 independently. Therefore, it is possible to fulfill the role of covering protection that prevents the stepping stone from hitting the power harness 34.
In addition, the electric power steering apparatus 1 including the brushless motor 14 according to the present embodiment is also arranged in the vicinity of the brushless motor 14 (harness outlet 26) without a plurality of power harnesses being drawn from the brushless motor 14. Since the other connector (not shown) provided at the tip of the power harness drawn out from the motor drive circuit 43 is detachably connected to one connector 35, the manufacturing cost of the electric power steering apparatus 1 can be reduced. Can be planned.

(Brushless motor of the third embodiment)
Next, FIG. 5 shows the brushless motor 14 of the third embodiment.
In the brushless motor 14 according to the present embodiment, a substantially box-shaped bracket mounting portion 47 provided with an insertion opening 47 a that opens toward the harness outlet 26 is integrally formed on the side surface of the connector housing 40 of the connector 35. An engaging opening 47b that communicates the inside and the outside of the bracket mounting portion 47 is formed at the bottom of the bracket mounting portion 47 that is spaced from the insertion opening 47a.

  The holding plate 48 of the motor connecting portion 22 arranged at the harness outlet 26 is orthogonal to the plate-like holding portion 48a fixed to the end surface of the harness outlet 26 facing the connector 35 and the holding portion 48a. A plate-like bracket portion 48b inserted into the bracket mounting portion 47 from the insertion opening portion 47a, and a member that is provided at the tip of the bracket portion 48b and engages with the periphery of the engagement opening portion 47b of the bracket mounting portion 47. It is comprised with the piece 48c.

  The engagement piece 48c is elastically deformed when moving in the bracket mounting portion 47 together with the bracket portion 48b, and is elastically restored to engage with the periphery of the engagement opening portion 47b when moving to the engagement opening portion 47b. . In this way, the engagement piece 48c engages with the peripheral edge of the engagement opening 47b so that the holding plate 48 and the connector housing 40 are detachably integrated, so that the connector 35 is connected to the flange 16 via the holding plate 48. Is supported by the cylindrical coupling portion 25.

  Therefore, in the present embodiment, the bracket mounting portion 47 provided on the side surface of the connector housing 40 and the bracket portion 48b of the holding plate 48 fixed to the harness outlet 26 are integrated, so that the connector 35 having a general structure. Can be reliably supported on the cylindrical coupling portion 25 of the flange 16 via the holding plate 48, and thus the manufacturing cost of the brushless motor 14 can be reduced.

  In addition, the electric power steering apparatus 1 including the brushless motor 14 in which the bracket mounting portion 47 provided in the connector housing 40 of the present embodiment and the bracket portion 48b of the holding plate 48 fixed to the harness outlet 26 are integrated is also provided. Since the length of the power harness 34 can be set shorter than a conventional structure in which a plurality of power harnesses are pulled out from the motor as in the prior art, the manufacturing cost of the electric power steering apparatus 1 can be reduced. Can do.

(Brushless motor of the fourth embodiment)
Next, FIG. 6 shows the brushless motor 14 of the fourth embodiment.
The holding plate 48 of the brushless motor 14 of the present embodiment includes a plate-like holding portion 48a fixed to an end surface of the harness outlet 26 facing the connector 35, and a bracket mounting portion 47 orthogonal to the holding portion 48a. A plate-like bracket portion 48b inserted from the insertion opening 47a and a cover integrally provided near the intersection of the holding plate 48 and the bracket portion 48b, and surrounds the outer periphery of the three power harnesses 34 by approximately a half circumference. The shape includes a portion 48d.

  According to the present embodiment, the same effect as that of the third embodiment can be obtained, and the cover portion 48d of the holding plate 48 surrounds the outer periphery of the three power harnesses 34 by approximately a half circle, so that the stepping stones It can serve as a covering protection that prevents the power harness 34 from being hit.

(Brushless motor of the fifth embodiment)
Next, FIG. 7 shows the brushless motor 14 of the fifth embodiment.
The holding plate 48 of the brushless motor 14 according to the present embodiment extends in a plate-like holding portion 48a fixed to the end surface of the harness pull-out port 26 and in a direction perpendicular to the hold portion 48a and away from the harness pull-out port 26. The intermediate plate portion 48e and the plate-like bracket portion 48f extending orthogonally from the intermediate plate portion 48e and parallel to the holding portion 48a are provided.
An engagement piece 48c that engages with the periphery of the engagement opening 47b of the bracket mounting portion 47 provided in the connector housing 40 is provided at the tip of the bracket portion 48f that extends parallel to the holding portion 48a. .

  By attaching the bracket portion 48f of the holding plate 48 fixed to the harness outlet 26 to the bracket mounting portion 47 provided on the side surface of the connector housing 40, the connector 35 is arranged in parallel to the motor shaft M. Further, the three power harnesses 34 whose other end portions are electrically connected to the connector 35 are drawn out from the harness outlet 26 in the motor shaft M direction and are electrically connected to the metal terminals of the connector 35.

According to the present embodiment, the same effects as those of the third embodiment can be obtained, the bracket portion 48f extending in the direction of the motor axis M of the holding plate 48 is attached to the bracket attachment portion 47, and the connector 35 is connected to the motor shaft. Since it arrange | positions so that it may become parallel to M, a radial direction dimension can reduce and the small brushless motor 14 can be provided.
Moreover, since the electric power steering apparatus 1 using the brushless motor 14 of the present embodiment is downsized, the degree of freedom in layout can be improved.

(Brushless motor of the sixth embodiment)
Furthermore, FIG. 8 shows the brushless motor 14 of the sixth embodiment.
As in the third embodiment, the brushless motor 14 of the present embodiment has a substantially box-shaped bracket mounting portion provided with an insertion opening 47a that opens toward the harness outlet 26 on the side surface of the connector housing 40 of the connector 35. 47 is formed integrally, and an engagement opening 47b that communicates the inside and the outside of the bracket mounting portion 47 is formed at the bottom of the bracket mounting portion 47 spaced from the insertion opening 47a.

A plate-like holding plate 39 having the same structure as that of the first and second embodiments is fixed to the end surface of the harness outlet 26.
In this embodiment, a bracket portion 15c extending radially outward from the opening edge portion of the motor case 15 in the vicinity of the harness outlet 26 is integrally formed, and a bracket portion 15c is formed at the tip of the bracket portion 15c. An engagement piece 15 d that engages with the periphery of the engagement opening 47 b of the mounting portion 47 is formed.

  The engagement piece 15d is elastically deformed when moving in the bracket mounting portion 47 together with the bracket portion 15c, and is elastically restored to engage with the peripheral edge of the engagement opening 47b when moving to the engagement opening 47b. . In this way, the engagement piece 15d engages with the peripheral edge of the engagement opening 47b so that the motor case 15 and the connector housing 40 are detachably integrated, so that the connector 35 is connected to the motor case via the bracket portion 15c. Supported by

  Therefore, in this embodiment, the bracket mounting portion 47 provided on the side surface of the connector housing 40 and the bracket portion 15c formed integrally with the motor case 15 are detachably integrated, so that the connector 35 having a general structure is provided. Can be reliably supported on the motor case 15 via the bracket portion 15c, and thus the manufacturing cost of the brushless motor 14 can be reduced.

  The electric power steering apparatus 1 including the brushless motor 14 in which the bracket mounting portion 47 provided in the connector housing 40 of the present embodiment and the bracket portion 15c provided in the motor case 15 are integrated is also a motor as in the related art. Since the length of the power harness 34 can be set shorter than the structure in which a plurality of power harnesses are pulled out to the outside, the manufacturing cost of the electric power steering device 1 can be reduced.

In each embodiment, the case where the stator 17 is a developed core system in which metal core plates are stacked has been described. However, a split core system may be used.
In each embodiment, the case where the resolver 20 is applied as a rotation angle detector for detecting the rotor rotation angle has been described. However, the present invention is not limited to this, and a magnetic detection element such as a Hall element, a rotary encoder, or the like. Any rotation angle detector such as can be applied.

Moreover, in each embodiment, although the case where the brushless motor 14 was applied to the electric power steering apparatus was demonstrated, it is not limited to this, Rotation drive of arbitrary apparatuses, such as an electric brake device and other vehicle equipment, Can be applied as a source.
Further, the three powers shown in the fourth embodiment of FIG. 6 are provided on a part of the bracket portion 15c extending radially outward from the opening edge of the motor case 15 of the sixth embodiment shown in FIG. Providing a cover portion similar to the cover portion 48d that surrounds the outer periphery of the harness 34 by approximately half a circumference can prevent contact of the power harness 34 with other components.

It is a schematic block diagram which shows the electric power steering apparatus which uses the rotary electric machine which concerns on this invention. It is a figure which shows the rotary electric machine of 1st Embodiment which concerns on this invention. It is a figure which shows the principal part of the rotary electric machine of 1st Embodiment. It is a figure which shows the rotary electric machine of 2nd Embodiment which concerns on this invention. It is a figure which shows the rotary electric machine of 3rd Embodiment which concerns on this invention. It is a figure which shows the rotary electric machine of 4th Embodiment which concerns on this invention. It is a figure which shows the rotary electric machine of 5th Embodiment which concerns on this invention. It is a figure which shows the rotary electric machine of 6th Embodiment which concerns on this invention.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 ... Electric power steering device, 2 ... Steering mechanism, 3 ... Steering wheel, 4 ... Steering shaft, 4a ... Input shaft, 4b ... Output shaft, 5 ... Steering torque sensor, 6 ... Universal joint, 7 ... Lower shaft, 8 ... Universal joint, 10 ... steering gear, 10a ... pinion, 10b ... rack, 11 ... tie rod, 12 ... steering assist mechanism, 13 ... reduction gear, 14 ... brushless motor, 15 ... motor case (housing body, case), 15a ... motor Inner wall of the case, 15b ... motor case fitting portion, 15c ... bracket portion, 15d ... engagement piece, 16 ... flange (housing body), 17 ... stator, 18 ... rotor, 19 ... shaft, 20 ... resolver, 20r ... resolver Rotor, 20s ... Resolver stator, 21a ... Freon Bearing, 21b ... Rear bearing, 22 ... Motor connection part (power supply connection part), 23 ... Bearing fitting hole, 24 ... Bolt through hole, 25 ... Cylinder coupling part (housing body), 26 ... Harness outlet, 26a ... Grommet mounting hole (through hole), 27 ... stator core, 28 ... insulator, 29 ... coil, 30 ... terminal block, 31a ... rotor core, 31b ... magnet, 32 ... rotor cover, 33 ... resolver holder, 34 ... power harness, 35 ... Connector (power supply connector) 36 ... support spacer 36a ... first support surface (opposing surface) 36b ... second support surface (opposing surface) 36c ... first block 36d ... second block 37 ... bus bar 38 ... Grommet 39 ... Holding plate 40 ... Connector housing 41 ... Vehicle speed sensor 42 ... Control device 43 ... Motor Moving circuit, 44 ... sensor harness, 45a, 45b, 45c ... support spacer, 45a1, 45b1, 451 ... first support surface (opposing surface), 45a2, 45b2, 45c2 ... second support surface (opposing surface), 47 ... bracket Mounting part, 47a ... Insertion opening, 47b ... Engagement opening, 48 ... Holding plate, 48a ... Holding part, 48b ... Bracket part, 48c ... Engagement piece, 48d ... Cover part, 48e ... Intermediate plate part, 48f ... Bracket part, M ... motor shaft (rotary shaft of rotor), S ... motor internal space

Claims (4)

Built-in cylindrical stator around which coils of a plurality of phases are wound, a rotor disposed on the inner periphery of the stator, a rotation angle detector for detecting the rotation angle of the rotor, the stator and the rotation angle detector A housing main body, a power feeding connector disposed in the vicinity of the housing main body, a power feeding connecting portion for electrically connecting the power feeding connector and the coils of the plurality of phases, and an outer periphery of the housing main body and the power feeding connector. And a connector support part for supporting the power supply connector on the housing body,
The power supply connection portion is disposed through a through hole provided in the housing body, and one end of a harness positioned inside the housing body is electrically connected to the coils of a plurality of phases, A plurality of short power harnesses, the other end of the harness located outside being electrically connected to the power supply connector, and each of the plurality of power harnesses mounted in a through hole provided in the housing body And a holding plate for pressing the grommet against the housing body,
The connector support part is a bracket part that protrudes from the holding plate and extends to a position where the power supply connector is disposed, and the power supply connector is fixed to the bracket part,
The rotating electrical machine, wherein the bracket portion and the power supply connector are arranged along an outer periphery of the housing body so as to extend in a rotation axis direction of the rotor . Built-in cylindrical stator around which coils of a plurality of phases are wound, a rotor disposed on the inner periphery of the stator, a rotation angle detector for detecting the rotation angle of the rotor, the stator and the rotation angle detector A housing main body, a power feeding connector disposed in the vicinity of the housing main body, a power feeding connecting portion for electrically connecting the power feeding connector and the coils of the plurality of phases, and an outer periphery of the housing main body and the power feeding connector. And a connector support part for supporting the power supply connector on the housing body,
The power supply connection portion is disposed through a through hole provided in the housing body, and one end of a harness positioned inside the housing body is electrically connected to the coils of a plurality of phases, The other end of the harness located outside has a plurality of short power harnesses that are electrically connected to the power supply connector,
The housing body includes a cylindrical case that is open at one end and closed at the other end to accommodate at least the stator, and a flange that closes the opening of the case on the opening side of the case,
The connector support portion is a bracket portion that protrudes from an opening edge portion of the case and extends to a position where the power supply connector is disposed, and the power supply connector is fixed to the bracket portion,
The rotating electrical machine, wherein the bracket portion and the power supply connector are arranged along an outer periphery of the housing body so as to extend in a rotation axis direction of the rotor . Electric rotating machine according to claim 1 or 2, characterized in that it comprises a cover portion surrounding the periphery of the plurality of power harnesses branched from said bracket unit. An electric power steering apparatus using the rotating electrical machine according to any one of claims 1 to 3 as a motor that generates a steering assist force in a steering mechanism.

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