JP6329835B2 - Terminal structure of power distribution parts - Google Patents

Description

  The present invention relates to a terminal structure of a power distribution component for supplying power to a stator coil of a rotating electrical machine.

  2. Description of the Related Art Conventionally, in a power distribution component that supplies power to a stator coil of a motor (rotary electric machine) mounted on a hybrid vehicle or the like, a U-phase, V-phase, and W-phase lead frame is formed by a cable harness. (For example, refer to Patent Documents 1 and 2). In this power distribution component, one end of the cable harness is pulled out from the power distribution component main body, which is a collection of multiple cable harnesses corresponding to each phase, and the power supply terminal is connected to the leading end of the pulled out cable harness (hereinafter referred to as the “drawer harness”). Is provided.

JP 2005-229677 JP 2007-318923 A

However, in the conventional power distribution component, since the lead frame is formed by the cable harness, the lead harness portion provided with the power supply terminal at the tip is unstable. For this reason, the positional relationship between the power feeding terminal and the power feeding connector connecting the power feeding terminal and the positional relationship between the plurality of power feeding terminals corresponding to each phase are not stable.
As a result, when the power distribution component is assembled to the motor, it is necessary to finely adjust the position of the power supply terminal, which hinders assembly by an automatic machine and an inspection process after the assembly by the automatic machine.

  The present invention has been made paying attention to the above problem, and an object of the present invention is to provide a terminal structure of a power distribution component that can be easily assembled without requiring fine positional adjustment when the power distribution component is assembled.

In order to achieve the above object, a terminal structure of a power distribution component according to the present invention includes a power distribution component main body, a plurality of drawer harness portions, a plurality of power supply terminals, and a connecting member.
The power distribution component main body includes a plurality of cable harnesses connected to a stator coil of a rotating electrical machine, and a harness support member that integrally supports the plurality of cable harnesses.
The plurality of drawing harness portions are configured from one end portions of a plurality of cable harnesses drawn from the power distribution component main body.
The plurality of power supply terminals are provided at the tips of the plurality of lead-out harness portions.
The connecting member has flexibility and is provided between the power distribution component main body and the plurality of power supply terminals to connect the plurality of drawing harness portions.

Therefore, in the terminal structure of the power distribution component according to the present invention, the power supply terminal is provided at the tip by the flexible connecting member, and a plurality of the drawing harness portions drawn from the power distribution component body are connected.
Therefore, variation in the positions of the plurality of power supply terminals can be suppressed, and the positional relationship between the plurality of power supply terminals and the power supply connector that connects each power supply terminal and the positional relationship between the plurality of power supply terminals are stabilized. be able to.
This eliminates the need for fine position adjustment when assembling the power distribution components, and facilitates assembly. Further, since the connecting member has flexibility, it is possible to give flexibility to handling of the power supply terminal, improve workability at the time of assembly, and ensure ease of assembly. .

It is sectional drawing which shows the stator to which the terminal structure of the power distribution components of Example 1 was applied. It is a perspective view which shows the terminal structure of the power distribution components of Example 1. FIG. It is a top view which shows the terminal structure of the power distribution components of Example 1. FIG. FIG. 3 is an exploded perspective view of a connecting member according to the first embodiment. It is AA sectional drawing in FIG. (a) is BB sectional drawing in FIG. 4, (b) is CC sectional drawing in FIG.

  Hereinafter, the form for implementing the terminal structure of the power distribution component of this invention is demonstrated based on Example 1 shown in drawing.

Example 1
First, the configuration of the terminal structure of the power distribution component in the first embodiment will be described by dividing it into “the overall structure of the stator”, “the terminal structure of the power distribution component”, and “the detailed structure of the connecting member”.

[Overall structure of stator]
FIG. 1 is a cross-sectional view illustrating a stator to which a terminal structure of a power distribution component of Example 1 is applied. Hereinafter, the overall structure of the stator of the first embodiment will be described with reference to FIG.

The power distribution component 10 of the first embodiment is applied to, for example, a three-phase AC motor (rotary electric machine) serving as a drive source for a hybrid vehicle, and is provided in the stator 1 shown in FIG. The stator 1 has an annular shape with both ends open, and surrounds the outer periphery of a rotor (not shown).
The stator 1 includes a stator housing 2, an annular stator core 3, and a plurality of stator coils 4 attached to the inner peripheral side of the stator core 3.

  The stator housing 2 is a frame member to which the stator core 3 is fixed by press fitting or shrink fitting. The stator housing 2 has a shaft support portion 2a that supports a rotation shaft (not shown) at the center.

  The stator core 3 is formed by laminating a large number of steel plates, and has a large number of teeth 3 a protruding toward the center of the stator 1. Here, the stator core 3 is comprised from the division | segmentation core divided | segmented into the circumferential direction so that each one teeth 3a may be included.

The plurality of stator coils 4 are concentrated winding coils, each wound around one of the plurality of teeth 3a. The plurality of stator coils 4 are each supplied with a U-phase, V-phase, or W-phase power from a multiphase AC power source. Each stator coil 4 is configured by winding a winding around an insulator 3 b fitted in a tooth 3 a of the stator core 3.
Then, both ends of the winding of each stator coil 4 are led out to the coil end 5, and one end is concentrated and connected to the same potential via a neutral terminal (not shown). The other end is connected to the power distribution component 10.
The coil end 5 is a portion of the stator coil 4 that is located on the axial end surface of the stator core 3 (tooth 3a).

  The power distribution component 10 is a so-called bus ring that distributes and supplies power from a multiphase AC power source to the stator coils 4 of each phase, and is connected between the motor (stator 1) and the power source. The power distribution component 10 has an annular shape along the coil end 5 of the stator 1. The plurality of cable harnesses 11 a connected to each of the plurality of stator coils 4 are grouped for each phase and connected to a power supply connector (not shown). .

[Terminal structure of power distribution parts]
FIG. 2 is a perspective view illustrating a terminal structure of the power distribution component of the first embodiment. FIG. 3 is a plan view showing a terminal structure of the power distribution component of the first embodiment. Hereinafter, based on FIG.2 and FIG.3, the terminal structure of the power distribution components of Example 1 is demonstrated.

  As shown in FIG. 2, the power distribution component 10 includes a power distribution component main body 11, a plurality (three here) of lead-out harness portions 12 </ b> A to 12 </ b> C, a plurality (here three) of power supply terminals 13 </ b> A to 13 </ b> C, And a connecting member 14.

  The power distribution component body 11 includes a plurality of cable harnesses 11a connected to the plurality of stator coils 4, and a harness support member 11b that integrally supports the plurality of cable harnesses 11a.

  The cable harness 11a is formed of a flexible covered conductive wire, and is routed along the harness support member 11b. One end of the cable harness 11 a is provided with a coil connection terminal 11 c that is connected to any one of the stator coils 4. The coil connection terminal 11c is fixed to the harness support member 11b.

The harness support member 11b is formed of an insulating material such as a resin, and has an annular groove 11d that runs along the coil end 5 and routes the cable harness 11a inside, and a harness lead-out portion 11e that leads out the lead-out harness portions 12A to 12C. ,have.
Here, the harness lead portion 11e is formed by opening a part of the annular groove 11d outward, and the annular groove 11d and the harness lead portion 11e communicate with each other. Further, an engaged portion 11f for fixing the connecting member 14 is formed in the harness lead portion 11e.

  The plurality of drawing harness portions 12A to 12C are configured such that one end of the cable harness 11a having one end connected to the stator coil 4 is pulled out of the stator 1 at the harness drawing portion 11e, and the plurality of cable harnesses 11a are in phase with each other. It is composed by grouping them together. Here, the drawer harness portion 12A is the U phase, the drawer harness portion 12B is the V phase, and the drawer harness portion 12C is the W phase. In addition, each extraction harness part 12A-12C pulled out from the power distribution component main body 11 is covered with the insulating cover 12d.

  The plurality of power supply terminals 13A to 13C are metal terminals connected to respective tips of the plurality of lead harness portions 12A to 12C. At the center of each of the power supply terminals 13A to 13C, a connection hole 13d for connecting to a power supply connector (not shown) is formed.

  The connecting member 14 is provided between the power distribution component main body 11 and the power supply terminals 13A to 13C, and connects the plurality of drawing harness portions 12A to 12C. Further, the connecting member 14 is formed of resin, and the bending direction of the drawing harness portions 12A to 12C when the power supply terminals 13A to 13C are connected to a power supply connector (not shown), that is, the axial direction of the stator 1 (arrow in FIG. 2). It is flexible enough to be deformable in the direction indicated by.

[Detailed structure of connecting member]
FIG. 4 is an exploded perspective view of the connecting member of the first embodiment. 5 is a cross-sectional view taken along line AA in FIG. 6A is a sectional view taken along line BB in FIG. 4, and FIG. 6B is a sectional view taken along line CC in FIG. Hereinafter, based on FIGS. 4-6, the detailed structure of the connection member of Example 1 is demonstrated.

  As shown in FIG. 4, the connecting member 14 includes a fixed holder 15 fixed to the harness support member 11 b and a cover 16 attached to the fixed holder 15.

  The fixed holder 15 includes a fixed portion 15a, an extending portion 15b, and a terminal support portion 15c.

  A pair of the fixing portions 15a is provided here, and engages with the engaged portion 11f of the harness support member 11b to fix the connecting member 14 to the harness support member 11b. The fixing portion 15a has a claw 15d that is locked to the engaged portion 11f (see FIG. 5).

The extending portion 15b extends from the pair of fixed portions 15a along the drawing harness portions 12A, 12B, and 12C, and is disposed between the plurality of drawing harness portions 12A to 12C. That is, the extending portion 15b extending from one fixing portion 15a is disposed between the drawing harness portion 12A and the drawing harness portion 12B, and the extending portion 15b extending from the other fixing portion 15a is formed from the drawing harness portion 12B and the drawing harness. It arrange | positions between the parts 12C.
The extended portion 15b is formed with a constricted portion 15f on the side surface 15e. Here, the side surface 15e faces the bending direction of the drawing harness portions 12A to 12C when the power supply terminals 13A to 13C are connected to a power supply connector (not shown), that is, the axial direction of the stator 1 (the direction indicated by the arrow in FIG. 2). Surface. The constricted portion 15f is formed by denting the side surface 15e.
In addition, first and second claw engagement holes 15h and 15j into which first and second engagement claws 16f and 16j, which will be described later, of the cover 16 are inserted and engaged are respectively inserted into the distal end portions 15g of the extending portions 15b. And the guide hole 15k which is arrange | positioned between these 1st, 2nd nail | claw engaging holes and into which the guide 16k mentioned later of the cover 16 is inserted is formed.

The terminal support portion 15c is a flat plate portion that connects the distal end portions 15g of the pair of extending portions 15b and integrally supports the distal end portions of the plurality of drawing harness portions 12A to 12C and the plurality of power supply terminals 13A to 13C. . A pair of flanges 15m that prevent the power supply terminals 13A to 13C from falling off are formed at both ends of the terminal support portion 15c. And the width dimension between one extension part 15b and one flange 15m, the width dimension between the front-end | tip parts 15g of a pair of extension part 15b, the width between the other extension part 15b and the other flange 15m The dimension is set to a dimension at which any one of the power supply terminals 13A to 13C can be arranged.
Here, the power supply terminal 13A is disposed between the one extension portion 15b and the one flange 15m, the power supply terminal 13B is disposed between the tip portions 15g of the pair of extension portions 15b, and the other 13 C of electric power feeding terminals are arrange | positioned between the extension part 15b and the other flange 15m.

  The cover 16 includes a harness holding part 16a, a terminal holding part 16b, and a pair of connecting parts 16c.

The harness holding portion 16 a contacts the plurality of drawing harness portions 12 </ b> A to 12 </ b> C, and holds the drawing harness portions 12 </ b> A to 12 </ b> C integrally with the fixed holder 15. Further, on the harness contact surface 16d of the harness holding portion 16a, a harness pressing projection 16e extending in the parallel direction of the plurality of drawing harness portions 12A to 12C and a first claw engagement hole formed in the fixing holder 15 A pair of first engaging claws 16f that engage with 15h are formed (see FIG. 6A).
Here, the pair of first engaging claws 16f have protrusions that protrude toward the outside in the width direction of the harness holding portion 16a.

  The terminal holding portion 16 b contacts the plurality of power supply terminals 13 </ b> A to 13 </ b> C, and holds the power supply terminals 13 </ b> A to 13 </ b> C integrally with the fixed holder 15. Further, a terminal pressing projection 16h extending in the parallel direction of the plurality of power supply terminals 13A to 13C is formed on the terminal contact surface 16g of the terminal holding portion 16b (see FIG. 6B).

The pair of connecting portions 16c extend along the drawing harness portions 12A, 12B, and 12C, and connect the harness holding portion 16a and the terminal holding portion 16b. A second engaging claw 16j that engages with a second claw engaging hole 15j formed in the fixed holder 15 and a fixed holder 15 are formed on the surfaces of the connecting portions 16c facing the drawer harness portions 12A to 12C. A guide 16k inserted into the guide hole 15k is formed (see FIG. 6B).
Here, each of the second engaging claws 16j has a protrusion protruding toward the power distribution component main body 11. That is, the protruding direction of the protrusion of the first engaging claw 16f is different from the protruding direction of the protrusion of the second engaging claw 16j.

Next, the operation will be described.
First, “the problem of the terminal structure of the power distribution component of the comparative example” will be described, and subsequently, “the function of facilitating the assembly” of the terminal structure of the power distribution component of the first embodiment will be described.

In the terminal structure of the power distribution component of the comparative example, the connecting member 14 is not used, and only the drawing harness portions 12A to 12C are pulled out from the power distribution component main body 11.
That is, first, the power distribution component body 11 is formed by integrally supporting the plurality of cable harnesses 11a connected to the plurality of stator coils 4 by the harness support member 11b. And the other end part of the cable harness 11a having one end connected to the stator coil 4 is drawn out of the stator 1 from the power distribution component main body 11, and a plurality (three in this case) are collected together in the same phase. Drawer harness portions 12A to 12C are formed.

  Here, although each extraction harness part 12A-12C collects the several cable harness 11a and is covered with the insulating cover 12d, the cable harness 11a is a flexible covering conductive wire in the first place. Therefore, even if a plurality of flexible cable harnesses 11a are combined, they can be freely deformed, and the shapes of the respective drawing harness portions 12A to 12C are unstable.

And the electric power feeding terminal 13A-13C is provided in the front-end | tip of each drawer harness part 12A-12C. However, since the shapes of the respective drawing harness portions 12A to 12C are unstable, the positions of the power supply terminals 13A to 13C are also unstable.
Therefore, the positions of the power supply terminals 13A to 13C are not stable with respect to the power supply connectors for connecting the power supply terminals 13A to 13C, and the power supply terminals 13A to 13C are connected when the power supply terminals 13A to 13C are connected to the power supply connectors. Position adjustment to match the target position was necessary.

  Also, the positional relationship between the power supply terminals 13A to 13C is not stable. Therefore, position adjustment is required for each of the power supply terminals 13A to 13C, and position adjustment when connecting the power supply terminals 13A to 13C and the power supply connector is further complicated.

  And since it is necessary to adjust the position when connecting the power supply terminals 13A to 13C and the power supply connector, the assembly by the automatic machine and the automation of the inspection process are hindered. For example, the assembly equipment is provided with a guide or the like. Measures to automate are essential. Therefore, the manufacturing cost has been increased.

  Furthermore, since the positions of the power supply terminals 13A to 13C are unstable, the power supply terminals 13A to 13C and the power supply connector may interfere unnecessarily. In order to prevent such interference, the power distribution component 10 and the power supply connector It was necessary to tighten the dimensional regulation between. Therefore, it can be considered that the manufacturing cost of the power distribution component itself also increases.

[Easy assembly]
In the terminal structure of the power distribution component 10 according to the first embodiment, the lead harness portions 12A to 12C formed by collecting a plurality of flexible cable harnesses 11a are connected by a connecting member 14 having flexibility.

That is, the fixing holder 15 is fixed to the harness supporting member 11b by engaging the fixing portion 15a of the fixing holder 15 of the connecting member 14 with the engaged portion 11f formed on the harness supporting member 11b. At this time, the positions of the plurality of drawing harness portions 12A to 12C are adjusted so that the pair of extending portions 15b enter between the plurality of drawing harness portions 12A to 12C.
Then, when the plurality of lead-out harness portions 12A to 12C are placed on the terminal support portion 15c provided at the distal end portion 15g of the pair of extending portions 15b, the cover 16 is attached to the fixed holder 15.

That is, the pair of first engaging claws 16 f formed in the harness holding portion 16 a of the cover 16 is engaged with the first claw engaging holes 15 h formed in the fixed holder 15. Thereby, between the pair of extending portions 15b and the harness holding portion 16a, the plurality of drawing harness portions 12A to 12C are sandwiched, and rattling of each drawing harness portion 12A, 12B, 12C is suppressed.
Further, the second engaging claws 16 j formed in the pair of connecting portions 16 c of the cover 16 are engaged with the second claw engaging holes 15 j formed in the fixing holder 15. Accordingly, the plurality of power supply terminals 13A to 13C are sandwiched between the terminal support portion 15c and the terminal holding portion 16b, and the relative positions between the power supply terminals 13A, 13B, and 13C are stabilized.

  Thereby, the dispersion | variation in the position of several electric power feeding terminal 13A-13C provided in the front-end | tip of each drawer harness part 12A-12C can be suppressed, and when electric power feeding terminal 13A-13C is assembled | attached to an electric power feeding connector, electric power feeding terminal 13A. Fine position adjustment of ˜13C can be eliminated. For this reason, even if measures for automating the assembly are not performed, the assembly by the automatic machine and the automation of the inspection process can be established, and the cost can be reduced.

  In addition, since the positions of the power supply terminals 13A to 13C are stabilized, unnecessary interference between the power supply terminals 13A to 13C and the power supply connector can be prevented, so that the dimensional regulation between the power distribution component 10 and the power supply connector is tightened. This is unnecessary, and an increase in manufacturing cost of the power distribution component 10 itself can be suppressed.

Furthermore, since the connecting member 14 has flexibility, the positions of the power supply terminals 13A to 13C are not completely fixed. That is, for a slight misalignment, the positions of the power supply terminals 13A to 13C can be adjusted to the target position, and flexibility can be given to the handling of the power supply terminals 13A to 13C during assembly. .
For this reason, the workability | operativity at the time of an assembly | attachment can be improved and an assembly | attachment ease can be ensured.

In the terminal structure of the power distribution component 10 according to the first embodiment, the constricted portion 15f is formed on the side surface 15e of the extending portion 15b of the fixing holder 15 of the connecting member 14. Therefore, even if it is small force, the connection member 14 can be changed easily and workability | operativity at the time of the assembly | attachment of the power supply terminals 13A-13C and a power supply connector can be improved further.
Furthermore, by forming the constricted portion 15f, it is possible to reduce the load input to the fixed portion 15a along with the bending of the extending portion 15b. Thereby, the structure of the fixing | fixed part 15a can be simplified and the manufacturing cost of the connection member 14 can be reduced.

Moreover, in the first embodiment, the constricted portion 15f is bent in the bending harness portions 12A to 12C when the power supply terminals 13A to 13C are connected to the power supply connector (not shown) of the side surface 15e of the extending portion 15b, that is, the stator. 1 is formed on the surface facing the axial direction of 1 (the direction indicated by the arrow in FIG. 2). Therefore, it is possible to suppress variations in the positions of the power supply terminals 13A to 13C while improving the workability when the power supply terminals 13A to 13C and the power supply connector are assembled.
Moreover, even if the drawer harness portions 12A to 12C are deformed due to vibration after assembly or the like, the extending portion 15b can follow the deformation, and it is possible to prevent a burden on the drawer harness portions 12A to 12C.

In the first embodiment, the terminal support portion 15c that integrally supports the plurality of power supply terminals 13A to 13C is provided at the distal end portion 15g of the pair of extending portions 15b, and the cover 16 is attached to the fixed holder 15. Accordingly, the power supply terminals 13A to 13C are sandwiched between the terminal support portion 15c and the terminal holding portion 16b of the cover 16, and the drawing harness portions 12A to 12C are interposed between the pair of extending portions 15b and the harness holding portion 16a of the cover 16. Pinch.
For this reason, the relative position between the power supply terminals 13A, 13B, and 13C can be stabilized, and the connection workability when connecting the plurality of power supply terminals 13A to 13C to the power supply connector can be further improved. Moreover, since the shakiness of each drawer harness part 12A, 12B, 12C can be suppressed, it is possible to easily suppress the dimensional variation between the power distribution component body 11 and each of the power supply terminals 13A, 13B, 13C. As a result, the size management of the power distribution component 10 is facilitated, and the manufacturing cost of the power distribution component 10 itself can be reduced.

  Furthermore, in the terminal structure of the power distribution component 10 according to the first embodiment, the extending portion 15b having flexibility of the connecting member 14 is disposed between the plurality of drawing harness portions 12A to 12C. Therefore, the extending portion 15b can be arranged by effectively using the gap generated between the plurality of drawing harness portions 12A to 12C. And the installation space of the connection member 14 can be made small and it can prevent that this connection member 14 becomes obstructive at the time of the connection operation | work of electric power feeding terminal 13A-13C.

Next, the effect will be described.
In the terminal structure of the power distribution component 10 of the first embodiment, the effects listed below can be obtained.

(1) A power distribution component body 11 having a plurality of cable harnesses 11a connected to the stator coil 4 of the rotating electrical machine, and a harness support member 11b that integrally supports the plurality of cable harnesses 11a,
A plurality of lead harness portions 12A to 12C constituted by one end portions of a plurality of cable harnesses 11a drawn from the power distribution component main body 11, and
A plurality of power supply terminals 13A to 13C provided at the respective tips of the plurality of drawing harness portions 12A to 12C;
A connecting member 14 that has flexibility and is provided between the power distribution component main body 11 and the plurality of power supply terminals 13A to 13C and connects the plurality of drawing harness portions 12A to 12C;
It was set as the structure provided with.
This eliminates the need for fine position adjustment when assembling the power distribution component 10 and facilitates assembly.

(2) The connecting member 14 is
A fixing portion 15a fixed to the harness support member 11b;
An extending portion 15b extending from the fixed portion 15a along the plurality of drawing harness portions 12A to 12C and having a constricted portion 15f formed on the side surface 15e;
A terminal support portion 15c provided at a distal end portion 15g of the extending portion 15b and integrally supporting the plurality of power supply terminals 13A to 13C;
It was set as the structure which has.
Thereby, in addition to the effect of (1), the connecting member 14 can be easily deformed even with a small force, and the workability when assembling the power supply terminals 13A to 13C and the power supply connector can be further improved. it can. Further, it is possible to reduce the load input to the fixing portion 15a along with the bending of the extending portion 15b, simplify the structure of the fixing portion 15a, and reduce the manufacturing cost of the connecting member 14.

(3) The constricted portion 15f is a surface of the side surface 15e of the extending portion 15b that faces the bending direction of the drawing harness portions 12A to 12C when the plurality of power feeding terminals 13A to 13C are connected to the power feeding connector. It was set as the structure provided.
Thereby, in addition to the effect of (2), the workability at the time of the assembly of the power supply terminals 13A to 13C and the power supply connector can be improved, and variations in the positions of the power supply terminals 13A to 13C can be suppressed.

(4) The connecting member 14 is
A fixing portion 15a fixed to the harness support member 11b;
A flexible extending portion 15b extending from the fixed portion 15a along the plurality of drawing harness portions 12A to 12C;
A terminal support portion 15c provided at a distal end portion 15g of the extending portion 15b and supporting the plurality of power supply terminals 13A to 13C;
A harness holding portion 16a provided in the extending portion 15b and integrally holding the plurality of drawing harness portions 12A to 12C;
It was set as the structure which has.
As a result, in addition to any of the effects (1) to (3), the relative position between the power supply terminals 13A, 13B, and 13C is stabilized, and the connection when connecting the plurality of power supply terminals 13A to 13C to the power supply connector is performed. Workability can be further improved. Moreover, since the shakiness of each drawing harness part 12A, 12B, 12C can be suppressed, the dimensional management of the power distribution component 10 becomes easy, and the manufacturing cost of the power distribution component 10 itself can be suppressed.

(5) The extending portion 15b is configured to be disposed between the plurality of drawing harness portions 12A to 12C.
Thereby, in addition to the effect in any one of (2) to (4), the extending portion 15b can be arranged by effectively utilizing the gaps generated between the plurality of drawing harness portions 12A to 12C. Can be prevented from interfering during connection work of the power supply terminals 13A to 13C.

  The terminal structure of the power distribution component according to the present invention has been described based on the first embodiment. However, the specific configuration is not limited to the first embodiment, and the invention according to each claim of the claims. Design changes and additions are permitted without departing from the gist of the present invention.

In Example 1, although the example which provides the constriction part 15f in order to give flexibility to the extension part 15b of the connection member 14 was shown, it does not restrict to this. For example, the material for forming the connecting member 14 itself may have high flexibility, such as forming the connecting member 14 from rubber.
Moreover, the extension part 15b may exhibit the flat plate shape which mounts several drawer harness parts 12A-12C.

  Moreover, in Example 1, although the example used as the harness support member 11b which has the annular groove 11d which routes the cable harness 11a inside along the coil end 5 was shown, it is not restricted to this. For example, a plurality of holding members that collectively hold a plurality of locations of the plurality of cable harnesses 11a arranged in an annular shape may be used.

DESCRIPTION OF SYMBOLS 1 Stator 2 Stator housing 3 Stator core 4 Stator coil 5 Coil end 10 Power distribution component 11 Power distribution component main body 11a Cable harness 11b Harness support member 12A, 12B, 12C Draw-out harness part 13A, 13B, 13C Feeding terminal 14 Connecting member 15 Fixed holder 15a Fixed Portion 15b extending portion 15c terminal support portion 15e side surface 15f constricted portion 16 cover 16a harness holding portion 16b terminal holding portion 16c connecting portion

Claims (5)

A power distribution component main body having a plurality of cable harnesses connected to a stator coil of a rotating electrical machine, and a harness support member that integrally supports the plurality of cable harnesses,
A plurality of drawing harness parts composed of one end parts of a plurality of cable harnesses drawn from the power distribution component body;
A plurality of power supply terminals provided at the tip of each of the plurality of drawer harness portions;
A connecting member that has flexibility and is provided between the power distribution component main body and the plurality of power supply terminals, and connects the plurality of drawer harness portions,
A terminal structure of a power distribution component comprising: In the terminal structure of the power distribution component according to claim 1,
The connecting member is
A fixing portion fixed to the harness support member;
An extension part extending from the fixed part along the plurality of drawer harness parts and having a constricted part on the side surface;
A terminal support portion that is provided at a distal end portion of the extending portion and integrally supports the plurality of power supply terminals;
A terminal structure of a power distribution component, comprising: In the terminal structure of the power distribution component according to claim 2,
The terminal structure of a power distribution component, wherein the constricted portion is provided on a surface of the side surface of the extending portion that faces the bending direction of the drawing harness portion when the plurality of power feeding terminals are connected to a power feeding connector. In the terminal structure of the power distribution component according to any one of claims 1 to 3,
The connecting member is
A fixing portion fixed to the harness support member;
A flexible extending portion extending from the fixed portion along the plurality of drawing harness portions;
A terminal support that is provided at a distal end of the extending portion and supports the plurality of power supply terminals;
A harness holding portion that is provided in the extending portion and integrally holds the plurality of drawing harness portions;
A terminal structure of a power distribution component, comprising: In the terminal structure of the power distribution component according to any one of claims 2 to 4,
The extension part is disposed between the plurality of drawing harness parts. A terminal structure of a power distribution component.