DE60023089T2 - Alternator - Google Patents

Description

BACKGROUND OF THE INVENTION

1. Field of the invention

The The present invention relates to an alternator, e.g. from an internal combustion engine is driven and in particular concerns a stand construction for one Alternator used in a vehicle, such as a passenger vehicle or a truck.

2. Stand the technology

39 Fig. 15 is a perspective view of a stator of a conventional automotive alternator, as described in, for example, Japanese Patent No. 2927288; 40 is a perspective view illustrating a conductor segment, in the stand off 39 is used and the 41 and 42 FIG. 15 is perspective views of a front end and a rear end of a part of the stand, respectively. FIG 39 ,

This stand 300 includes: a stator core 301 ; a stator winding 302 in the stator core 301 is wound; and insulators 304 inside the slots 303 are attached, the insulators 304 the stator winding 302 opposite the stator core 301 isolate. The stator core 301 is a cylindrical multilayer core constructed by stacking thin steel plates constituting plate-shaped magnetic members and a number of slits 303 which extend axially and are arranged in a uniform circumferential pitch to open to the side of the inner periphery. The stator winding 302 is by connecting several short conductor segments 305 constructed in a predetermined winding pattern.

The conductor segments 305 are substantially U-shaped from an insulated copper wire material having a rectangular cross-section, and are slotted from an axial rear end 303 which are six slots apart (a pitch of a magnetic pole) introduced. Then, the end portions of the conductor segments become 305 extending at a front end, connected to each other around the stator winding 302 to build.

More precisely, become first conductor segments 305 from the rear end into first positions from the side of the outer periphery into first slots 303 and in second positions from the side of the outer periphery into second slots 303 and second conductor segments 305 from the rear end to third positions from the outer circumference side to the first slots 303 and in fourth positions from the outer circumference side to the second slots 303 in pairs of slots 303 inserted six slots apart. Thus, in each of the slots 303 four straight sections 305a the conductor segments 305 arranged so that they line up in the radial direction.

Then the end sections 305b the conductor segments 305 located at the first end at the first positions from the side of the outer circumference of the first slots 303 extend and end sections 305b the conductor segments 305 located at the front end at the second positions from the side of the outer circumference of the second slots 303 in a circumferential direction from the first slots 303 six slots away, joined to form a two-pass outer layer winding. Next are end sections 305b the conductor segments 305 located at the front end at the third positions from the side of the outer circumference of the first slots 303 extend and end sections 305b the conductor segments 305 located at the front end at the fourth positions from the side of the outer circumference of the second slots 303 clockwise six slots away from the first slots 303 extend, connected to form an inner layer winding with two rounds.

Next, the inner layer winding and the outer layer winding, passing through the into the pairs of slots 303 , which are six slots apart, inserted conductor segments 305 be formed, connected in series to one phase of the stator winding 302 to form with four rounds.

In total, six phases of the stator winding 302 each trained with four rounds alike. Then, two groups of three-phase stator winding sections are formed by connecting three phases of the stator winding 302 built in AC circuits.

In the conventional stand 300 constructed in this way are at the rear end of the stator core 301 turn portions 305c the conductor segment pairs 305 that are in the same pairs of slots 303 are introduced, strung together in the radial direction. As a result, the turning sections 305c arranged in two rows in the circumferential direction to form a rear end coil end group.

At the front end of the stator core 301 On the other hand, connecting portions are by connecting the end portions 305b the conductor segments 305 located at the first end at the first positions from the side of the outer circumference of the first slots 303 and the end sections 305b the Leiterseg mente 305 located at the front end at the second positions from the side of the outer circumference of the second slots 303 six slots away, formed and connecting portions are formed by connecting the end portions 305b the conductor segments 305 located at the front end at the third positions from the side of the outer circumference of the first slots 303 extend and the end sections 305b the conductor segments 305 located at the front end at the fourth positions from the side of the outer circumference of the second slots 303 six slots away, formed and arranged radially aligned. Consequently, connecting portions are formed by connecting the end portions 305b formed with each other in two rows in the circumferential direction to form a coil end group at the front end.

At the stand 300 In a vehicle alternator having the above structure, the coil end groups are constructed of a plurality of connection portions because the stator winding 302 by inserting short conductor segments 305 , which are generally U-shaped, into the slots 303 of the stator core 301 from the rear end and connecting the end portions 305b the conductor segments 305 , which extend out at the front end, is constructed, which favors the easy occurrence of short-circuit accidents, because the connecting portions easily short-circuit each other.

A large number of short conductor segments 305 must be in the stator core 301 and their end portions must be joined by welding, brazing, etc., whereby the handleability is significantly poor. Furthermore, the amount of each conductor segment 305 that in the slots 303 is introduced, be greater than the length of the stator core 301 which promotes damage to the insulation and reduction of the quality of the final product. In addition, when joining the end portions, short-circuiting between the joint portions due to spattered solder or molten welding material often occurs, whereby the mass producibility is significantly poor.

In contrast to the conventional structure of the conductor segments 305 Japanese Patent Publication No. HEI 8-298756 discloses a stator assembly constructed of a number of coil pieces which, by pre-winding a number of straight-line conductors, a number of times into a generally hexagonal shape and inserting the coil pieces into slots of core portions, which are divided semicircular, are constructed.

at this stand become the coil pieces in the slits of the semicircular introduced split core sections in an order radially outward. In other words first side portions of the hexagonal coil pieces in an inner circumferential position positioned corresponding to a location on the inside of the slots, and second side portions are positioned in an outer circumferential position, the one on the outside corresponds to a predetermined number of slots away.

Even though the orientation of the coil ends extending from the slots at this stand is good, when joining the split core sections together, wherein the first side portions of the coil pieces already in the slots a first split core section, but because it is necessary is, the process of introducing the coil ends into the slots of a second split core section simultaneously with the process of joining the split core sections, a temporary holding device or the like can be used to perform a complicated process, which significantly reduces productivity deteriorated.

If new spool pieces in the outer circumferential position behind the coil pieces, previously inserted in the inner circumferential position of the slots, introduced it is necessary to lift the previous spool pieces and because this involves turning and lifting, one remains Number of rectilinear conductors of the side sections of previously inserted coil ends in the slots and there are limitations the space factor of Head in the slots to improve.

Japanese Patent Publication No. HEI 9-103052 discloses a stand 400 in that winding groups formed in a straight shape are inserted into a straight base core in a slot depth direction, and the base core is bent into a cylindrical shape in a later process to improve the space factor of the conductors in the slots. 43 is an overall perspective of the stand 400 which was produced by this method. Although the insertion of the winding groups is significantly improved because the winding dimension has straight bridge sections extending between the slots 401 extend in the circumferential direction, the orientation of the coil ends 402 coming out of the slots 401 extend significantly, resulting in increased radial dimensions and short circuits between the conductor segments in the coil ends 402 leads. Moreover, due to the straight base core being formed into a cylindrical shape without modifications, a significant amount of bending force is required and springback is great, causing problems such as the formation of gaps the bonding surfaces of the resulting cylinder and deterioration of the output power and magnetic noise, etc. leads.

In the conventional automotive alternator disclosed in Japanese Patent No. 2927288, there has been a problem of a plurality of short conductor segments 305 in the stator core 301 had to be inserted and whose end portions had to be joined by welding, soldering, etc., which significantly deteriorated the handleability and when joining the end portions, often caused a short circuit between the connecting portions due to spattered solder or molten welding material, whereby the mass producibility was significantly poor.

at the alternator of Japanese Patent Publication No. HEI 8-298756 The problems consisted in that the assembly process of the stand bad is, being a complicated process using a temporary Holding device is required and in that the space factor the ladder in the slots was bad, etc.

In the automotive alternator disclosed in Japanese Patent Publication No. HEI 9-103052, the orientation of the coil ends 402 coming out of the slots 401 extend significantly, resulting in increased radial dimensions and a short circuit between the conductors in the coil ends 402 and a significant amount of bending force is required to bend the linear base core into a cylinder without special treatment, whereby the springback is strong and problems such as the formation of gaps on the joint surface of the resulting cylinder, the deterioration of the output and magnetic disturbances etc. leads.

The US-A-5,982,068 discloses an alternator according to the preamble of claim 1.

SUMMARY THE INVENTION

The The present invention aims to solve the above problems and It is an object of the present invention to provide an alternator with simplified production, which is an improvement the orientation of the coil ends, the space factor of the conductors in the Slits, etc. allows.

To this purpose is in accordance with the present Invention proposed an alternator, comprising: the multi-phase Stator winding, comprising a number of winding sections, in each of which a continuous wire is wound in such a way that it intermittently a predetermined number of slots in the slots alternately an inner situation and an outer situation occupied in the slot depth direction, the wire outside the slots on axial end surfaces of the stator core rewound is and where the stator core is provided with a contact portion extending axially, so that the stator core by joining together from ends of the stator core at the abutment portion assumes an annular shape.

SHORT DESCRIPTION THE DRAWINGS

1 FIG. 10 is a cross section of a vehicular alternator according to Embodiment 1 of the present invention; FIG.

2 is a perspective of the stand 1 ,

3 is an end elevation view showing the connections of one phase of the stator winding group 1 explains;

4 is a circuit diagram of the vehicle alternator 1 ;

5 is a cross-section of the stand 1 ;

6 is a cross section of the stator core 1 ;

7 Fig. 12 is a diagram showing the winding subsections extending into the stator core 1 are introduced;

8th is a perspective of a stator of a vehicle alternator according to embodiment 2 the present invention;

9 is a cross section of the stator core 8th ;

10 is a partial cross section of the stator core 1 along the line XX;

11 FIG. 12 is a diagram showing an outer peripheral core portion extending over an inner circumferential core portion. FIG 9 was added;

12 Fig. 12 is a perspective view of a stator of a vehicular alternator according to Embodiment 3 of the present invention;

13 is a partial cross section of the stator core 12 ;

14 is a diagram showing an intermediate step of the manufacturing process for a Outer circumferential core section explained;

15 is a cross section of the outer peripheral core portion 14 along the line XV-XV;

16 Fig. 12 is a perspective view of a stator of a vehicular alternator according to Embodiment 4 of the present invention;

17 is a cross section of the stator core 16 ;

18 Fig. 12 is a diagram showing the connections of one phase of the stator winding group 16 explains;

19 Fig. 12 is a diagram explaining the manufacturing method of the coil groups which are part of the stator winding used in the automotive alternator according to Embodiment 4 of the present invention;

20 Fig. 12 is a diagram explaining the manufacturing method of the winding groups which are part of the stator winding used in the automotive alternator according to Embodiment 4 of the present invention;

21 (a) and 21 (b) 10 are an end elevational view and a plan view showing an inner layer wire group that is part of the stator winding used in the automotive alternator according to Embodiment 4 of the present invention;

22 (a) and 22 (b) FIG. 12 is an end elevational view and a plan view showing an outer layer wire group that is part of the stator winding used in the automotive alternator according to Embodiment 4 of the present invention; FIG.

23 Fig. 12 is a perspective view showing a part of a wire which is part of the stator winding used in the automotive alternator according to Embodiment 4 of the present invention;

24 Fig. 12 is a diagram explaining the arrangement of the wires which are part of the stator winding used in the automotive alternator according to Embodiment 4 of the present invention;

25 is a perspective of the base core of the inner peripheral core section 17 before bending;

26 (a) to (d) are graphs showing the steps of inserting the winding into the base core 25 explain;

29 is a partial cross section of the stator core 17 ;

30 Fig. 15 is a partial cross section of a stator core used in a vehicular alternator according to Embodiment 5 of the present invention;

31 Fig. 10 is an overall perspective view of a stator used in a vehicular alternator according to Embodiment 6 of the present invention;

32 is a cross section of the stator core 31 ;

33 Fig. 12 is a cross section of a stator core used in a vehicular alternator according to Embodiment 7 of the present invention;

34 is a perspective of a base core of an inner circumference kernel section 33 before bending;

35 FIG. 12 is a cross section of a stator core used in a vehicular alternator according to Embodiment 8 of the present invention; FIG.

36 is a partial enlargement of the stator core 35 ;

37 Fig. 10 is a partial cross section of a stator core used in a vehicular alternator according to Embodiment 9 of the present invention;

38 is a partial enlargement of the stator core 37 ;

39 Fig. 11 is a perspective of a stator in a vehicular alternator according to Embodiment 10 of the present invention;

40 is a cross section showing a stator core in the stand 39 is used;

41 Fig. 12 is a perspective view of a stator of a conventional vehicle alternator;

42 is a perspective showing a ladder segment in the stand 41 is used;

43 is a perspective of the front end of part of the stand 41 ;

44 is a perspective of the back end of a part of the stand 41 ; and

45 Fig. 10 is a perspective of another example of a stator of a conventional vehicle alternator.

PRECISE DESCRIPTION THE PREFERRED EMBODIMENTS

Of the Structure of the vehicle alternators according to the preferred embodiments The present invention will now be described with reference to the drawings explained.

Embodiment 1

1 FIG. 15 is a cross section showing the structure of a vehicular alternator according to Embodiment 1 of the present invention; FIG. 2 is a perspective of the stator of this vehicle alternator, 3 FIG. 4 is an end elevational view explaining the interconnections of one phase of the stator winding group of this vehicle alternator; FIG. 4 is a circuit diagram of this vehicle alternator, 5 is a partial cross section of the stand 1 . 6 is a partial cross section of the stator core 1 and 7 is a partial cross section of the stand 5 ,

This alternator comprises: a housing 3 made of a front aluminum half 1 and a rear aluminum half 2 is constructed; a wave 6 in the case 3 is arranged and attached to a first end thereof pulley 4 having; a Lundell runner 7 who is at the shaft 6 is attached; Fan 5 attached to both axial end surfaces of the rotor 6 are attached; a stand 8th which is attached to an inner wall of the housing 3 is attached; slip rings 9 at a second end of the shaft 6 are attached to the runner 7 to supply electrical power; a brush pair 10 that on the slip rings 9 slides; brush holder 11 that the brushes 10 take up; rectifier 12 that with the stand 8th are electrically connected to the in the stand 8th converted AC to DC; a heat sink 17 above the brush holder 11 is provided; and a regulator 18 by means of adhesive to the heat sink 17 is attached to the height of the AC voltage in the stator 8th is generated, set.

The runner 7 includes a rotor coil 13 for generating a magnetic flux on the passage of electric current, a first and second pole core 20 and 22 , which are arranged so that they the rotor coil 13 Cover, wherein by the magnetic flux magnetic poles in the pole cores 20 and 21 be generated. The two pole cores 20 and 21 are made of metal and each have eight claw-shaped magnetic poles 22 and 23 which are fixed to the shaft so as to be equally spaced around the outer peripheral edges and face each other so as to be engaged with each other.

As it is in 2 is illustrated, the stand comprises 8th a cylindrical stator core 15 which is made up of a multi-layered core with a number of slots 15a is formed, which extend axially in a predetermined pitch in the circumferential direction; a polyphase stator winding 16 in the stator core 15 is wound; and insulators 19 in each of the slots 15a are provided to the polyphase stator winding 16 opposite the stator core 15 electrically isolate. The multiphase stator winding 16 includes a number of windings, each containing a wire 30 outside the slots 15a at end surfaces of the stator core 15 is wound back and wound in a wave winding, that in slots, which are a predetermined number of slots apart, alternately occupies an inner layer and an outer layer in the slot depth direction. In the local case is the stator core 15 with ninety-six slots 15a formed in a uniform pitch to two groups of the three-phase stator winding sections 160 so that the number of slots each accommodating one phase of the winding sections, the number of magnetic poles (sixteen) in the rotor 7 equivalent. As a wire 30 For example, a long insulated copper wire material having a rectangular cross section is used.

air intake openings 1a and 2a are in axial end surfaces of the front half 1 and the back half 2 trained and air outlet openings 1b and 2 B are in two shoulder sections on the outer circumference of the front half 1 and the back half 2 opposite the radial outside of the coil end at the front end and rear end 16a and 16b the stator winding 16 arranged.

The stator core 15 is made up of eight subdivided core sections 15A built up, which is radial through the teeth 51 are cut apart, with the divided core sections 15A are provided with abutment sections. The divided core sections 15A are formed by bonding 0.35 mm thick SPCC material and bonded to an outer peripheral portion by laser welding. The radial dimension t1 of a core back section 50 each of these divided core sections 15A is 3.5 mm and a width dimension of the slots 15a is 1.9 mm from a bottom section to an opening section 15b essentially constant.

Next, the winding structure of one phase of the stator winding group becomes 161 with reference to 3 explained in detail.

A phase of the stator winding group 161 is from first to fourth winding subsections 31 to 34 built, each made of a wire 30 are formed. The first winding subsection 31 is by wave winding a first wire 30 in every sixth slot from slots # 1 to # 91, leaving it in the slots 15a alternately occupying a first position from one side of the outer circumference and a second position from the side of the outer circumference. The second winding subsection 32 is by wave winding a wire 30 in every sixth slot from slot # 1 to # 91, leaving it in the slots 15a alternately occupying the second position from the outer circumference side and the first position from the outer circumference side. The third winding subsection 33 is by wave winding a wire 30 in every sixth slot from slot # 1 to # 91, leaving it in the slots 15a alternately occupying a third position from the outer circumference side and a fourth position from the outer circumference side. The fourth winding subsection 32 is by winding a wire in every sixth slot from slot # 1 to # 91, leaving it in the slots 15a alternately occupies the fourth position from the side of the outer periphery and the third position occupied by the side of the outer periphery. The wires 30 are arranged so that they are within each slot 15a in a row of four wires, with the longitudinal direction of their rectangular cross-sections aligned in the radial direction.

At a first end of the stator core 15 are a first end section 31a of the first winding subsection 31 extending from slot No. 67 and a first end portion 33a of the third winding subsection 33 , which extends from slot No. 61, connected, and a second end portion 32b of the third winding subsection 33 extending from slot No. 67 and a first end portion 31b of the fourth winding subsection 34 which extends from slot No. 61 are connected and in addition are a second end portion 34b of the fourth winding subsection 34 extending from slot number 55 and a first end portion 32a of the second winding subsection 32 extending from slot No. 61 connected to a stator winding group 161 to form, which has four winding circuits.

In addition, the second end section becomes 31b of the first winding subsection 31 a connection line (O) and the second end portion 32b of the second winding subsection 32 becomes a star point (N).

In total, six phases will be connected to stator winding groups 121 in a similar manner by moving the slots 15a into which the wires 30 are wound, each time formed around a slot. Then, as it is in 4 is shown, the stator winding groups 161 connected in star circuits to the two groups of three-phase stator winding sections 160 and each of the three-phase stator winding sections 160 is with its own rectifier 12 connected. The rectifier 12 are connected in parallel, so that the output DC current is combined.

In addition, the two groups of the three-phase stator winding sections become 160 in the stator core 15 installed so that they have a phase difference of 30 °.

Thus, the wires 30 that the first to fourth winding subsections 31 to 34 form, each wound in a wave winding such that they are made of first slots 15a at the end surfaces of the stator core 15 out, wind back and into second slots 15a six slots away. Each of the wires 30 is also wound so as to alternately occupy the inner layer and the outer layer relative to the slot depth direction (the radial direction) in every sixth slot.

turn portions 30a the wires 30 extending from the stator core 15 extend and recoil, forming the coil ends. The turnaround sections 30a at both axial ends of the stator core 15 are formed substantially in the same shape, are circumferentially and radially spaced apart and circumferentially arranged neatly in two rows to coil end groups 16a and 16b to build.

In the vehicular alternator of the above construction, first, the cylindrical polyphase stator winding 16 educated. Then each of the divided core sections becomes 15A from the side of the outer periphery of the polyphase stator winding 16 pressed radially inward so that the first to fourth winding subsections 31 to 34 through each of the opening sections 15b in each of the slots 15a be introduced. Before this insertion, the opening sections become 15b every slot 15a with the insulators 19 covered, leaving the insulators 19 as a result of introducing the first to fourth winding subsections 31 to 34 between the first to fourth winding subsections 31 to 34 and inner wall surfaces of the slots 15a the divided core sections 15A are arranged.

In the vehicle alternator constructed in this manner, electric power is supplied from a battery (not shown) via the brushes 10 and the slip rings 9 the rotor coil 13 supplied, whereby a magnetic flux is generated. The claw-shaped magnetic poles 22 of the first pole core 20 are magnetized by this magnetic flux as north poles and the claw-shaped magnetic poles 23 of the first pole core 21 are magnetized as south poles. At the time, to which torque from the engine via the belt and the pulley 4 on the wave 6 is transferred, becomes the runner 7 turned. Thus, a rotating magnetic field is applied to the multi-phase stator winding 16 applied, creating an electromotive force in the polyphase stator winding 16 is produced. This alternating electromotive force passes through the rectifier 12 and is converted to DC, with the amount of current through the regulator 18 is set and the battery is recharged.

At the rear end, outside air is through the air intake openings 2a , which correspond to the heat sinks of the rectifier 12 and the heat sink 17 of the regulator 18 are arranged by the rotation of the runners 5 sucked in, flows along the axis of the shaft 6 , cools the rectifier 12 and the regulator 18 and then gets through the runners 5 centrifugally deflected, causing the coil end group 16b the multiphase stator winding 16 Cooled at the tail end before going through the air outlet openings 2 B is output to the outside. At the same time outside air is at the front end by the rotation of the runners 5 axially through the air intake openings 1a sucked in and then through the fan 5 centrifugally deflected, causing the coil end group 16a the multiphase stator winding 16 is cooled at the front end before passing through the air outlet openings 1b is output to the outside.

In this way, according to Embodiment 1, the operation of installing the polyphase stator winding becomes 16 in the stator core 15 , Compared with the prior art, in which a plurality of conductor segments 305 one after the other must be inserted into the slots by forming the cylindrical multi-phase stator winding 16 Then press each of the subdivided core sections 15A from the side of the outer periphery of the polyphase stator winding 16 radially inward, such that the first to fourth winding subsections 31 to 34 through each of the opening sections 15b in each of the slots 15a be introduced.

In addition, the insulators can 19 during the insertion of the first to fourth winding subsections 31 to 34 easily between the first to fourth winding subsections 31 to 34 and the inner wall surfaces of the slots 15a to be ordered. Because the first to fourth winding subsections 31 to 34 that the multiphase stator winding 16 form, each of a wire 30 (continuous wire) are constructed, it is not necessary, a plurality of short conductor segments 305 in the stator core 301 to introduce and end sections 305b by welding, soldering, etc. together, as in the conventional stand 308 was required, thereby allowing the productivity of the stand 8th significantly improve.

Since the coil ends through the turning sections 30a the wires 30 are formed, the compounds of the coil end groups 16a and 16b the first and second end portions of the first to fourth winding subsections 31 to 34 and the bridging connecting connecting sections, thereby significantly reducing the number of connections. Since the occurrence of short circuit accidents accompanying the insulation loss due to the connection process can be suppressed, superior insulation can be obtained. Further, the conductors are not softened by welding, thereby increasing the strength of the stator as a whole, and making it possible to reduce magnetic noise.

The coil end groups 16a and 16b are by properly arranging the turnaround sections 30a built in rows in the circumferential direction so that they do not interfere with each other. Thus, as compared with the conventional coil end groups in which the end portions 305b the conductor segments 305 interconnected, the height to which the coil end groups from the stator core 15 extend, reduced. Thus, the wind resistance in the coil end groups becomes 16a and 16b reduces, reducing the wind noise due to the rotation of the rotor 7 is possible. Also, the coil leakage reactance in the coil ends is reduced, thereby improving the output performance and the efficiency.

Four wires 30 are arranged so that they are in each slot 15a in a row radially adjoin one another and the turning sections 30a are arranged so that they line up in the circumferential direction in two rows. The turnaround sections 30a , the coil end groups 16a and 16b are each divided radially into two rows, thereby allowing the height to which the coil end groups 16a and 16b from the stator core 15 extend out, reduce. As a result, the wind resistance of the coil end groups becomes 16a and 16b reduces, reducing the wind noise due to the rotation of the rotor 7 is possible.

Because the straight sections 30b the wires 30 are formed with a rectangular cross section, fits the cross-sectional shape of the straight sections 30b neat in the shape of the slots 15a if the straight sections 30b in the slots 15a are included. Thus, the insertion becomes the divided core sections 15A in the multiphase stator winding 16 improved and the space factor of the wires 30 in the slots 15a is increased in an easy way, resulting in improved heat transfer from the wires 30 on the stator core 15 is possible.

Embodiment 2

8th is a perspective of a stand 60 a vehicular alternator according to Embodiment 2 of the present invention, 9 is a cross section of a stator core 61 in the stand 60 out 8th and 10 is a partial cross section of the stator core 61 out 9 along the line XX. Moreover, in each of the following embodiments, portions that are the same as or corresponding to those in Embodiment 1 are given the same reference numerals.

In this embodiment, a stand comprises 60 a cylindrical stator core 61 which is made up of a multi-layered core with a number of slots 61a is formed, which extend axially in a predetermined pitch in the circumferential direction; a polyphase stator winding 16 on the stator core 61 is wound; and insulators 19 in each of the slots 15a are installed around the polyphase stator winding 16 opposite the stator core 61 electrically isolate.

The stator core 61 comprising: an inner circumferential core portion 62 that with ninety-six slots 15a is formed in the same pitch, so as two groups of the three-phase stator winding sections 160 so that the number of slots each accommodating one phase of the winding sections is equal to the number of magnetic poles (sixteen) of the rotor 7 corresponds; and a tubular outer circumferential core portion 63 in press fit over the inner circumferential core section 62 is added. The inner peripheral core section 62 is made up of eight subdivided core sections 62A built up, which is radial through the teeth 51 are cut apart. The divided core sections 15A are provided with abutment sections, formed by joining SPCC material with a thickness of 0.35 mm and integrated by laser welding at the outer peripheral portion. The radial dimension t1 of the core back section 50a each of these divided core sections 62A is 1 mm and a thickness dimension t2 of the outer peripheral core portion 63 is 2.6 mm. In the vehicular alternator of the above construction, the cylindrical polyphase stator winding first becomes 16 educated. Then each of the divided core sections becomes 62A from the side of the outer periphery of the polyphase stator winding 16 pressed radially inward so that the first to fourth winding subsections 31 to 34 through each of the opening sections 15b in each of the slots 15a be introduced. Before this insertion, the opening sections become 15b each of the slots 15a through the insulators 19 covered, leaving the insulators 19 as a result of introducing the first to fourth winding subsections 31 to 34 between the first to fourth winding subsections 31 to 34 and the inner wall surfaces of the slots 15a the divided core sections 62A are arranged. Thereafter, the inner peripheral core portion becomes 62 in press fit into the outer circumferential core section 63 introduced as it is in 11 is shown to the production of the stand 60 complete.

According to Embodiment 2, the process of installing the polyphase stator winding becomes 16 in the stator core 61 , Compared with the prior art, in which a plurality of conductor segments 305 one after the other had to be inserted into the slots, by first forming the cylindrical multi-phase stator winding 16 and then pressing each of the divided core sections 62A from the side of the outer periphery of the polyphase stator winding 16 radially inward, such that the first to fourth winding subsections 31 to 34 through each of the opening sections 15b in each of the slots 15a be introduced.

The inner peripheral core section 62 is constructed by connecting 0.35 mm thick steel plates, but since the radial dimension t1 of the core back section 50a of the inner peripheral core portion 62 As compared with that of Embodiment 1, which is bent, straight-shaped divided core portions can be easily bent to the divided core portions 62A to build. Since the radial dimension t1 of the core back section 50a of the inner peripheral core portion 62 is small and the strength of the inner peripheral core section 62 is low, the entire divided core section becomes 62A by restricting the outer peripheral core portion 63 compressed radially outward inwards, whereby gaps between the inner peripheral core portion 62 and the outer circumferential core portion 63 can be reduced and allowed to suppress reductions in magnetic performance.

Due to the fact that the inner peripheral core section 62 from the outside by attaching the cylindrical outer peripheral core portion 63 over the inner circumferential core section 62 is supported, a structurally preferred degree of radially inner roundness can be achieved in an easy way and the strength of the stator core 61 itself is improved, whereby the occurrence of electromagnetic noise, etc. can be suppressed.

Embodiment 3

12 is a perspective of a stand 65 a vehicle alternator according to Embodiment 3 of the present invention and 13 is a partial cross section of the stator core 67 out 12 ,

Embodiment 3 differs from Embodiment 2 in that an outer peripheral core portion 66 of the stand 65 is constructed by connecting annular plate-shaped elements and their integration by laser welding.

Because the outer peripheral core section 66 In Embodiment 3 has a multilayer structure, the occurrence of eddy currents on surfaces of the outer peripheral core portion 66 can be suppressed, whereby the magnetic performance can be improved while the effects of the embodiment 2 are achieved.

In addition, the outer peripheral core portion is 66 by connecting a number of layers of annular plate-shaped elements, but as shown in FIG 14 and 15 is shown, the stator core 67 also by forming an outer peripheral core portion 68 by winding a long plate-shaped magnetic element 69 in a spiral shape and attaching the outer peripheral core portion 68 are formed on the outside of an inner peripheral core portion (not shown). In this case, the production of the stator core 67 proportionally lighter by eliminating the need for a punching operation.

Embodiment 4

16 is a perspective of a stand 70 a vehicle alternator according to Embodiment 4 of the present invention. 17 is a cross section of the stator core 71 out 16 . 18 FIG. 12 is a diagram showing the connections in one phase of the stator winding group in FIG 16 explains 19 and 20 are diagrams explaining the manufacture of the winding groups forming part of the stator winding, 21 (a) and 21 (b) are graphs showing an inner ply group forming part of the stator winding in FIG 16 is 21 (a) is an end top view and 21 (b) is a top view 22 (a) and 22 (b) For example, graphs showing an outside wire group are part of the stator winding 16 is 22 (a) is an end top view and 22 (b) is a top view 22 is a perspective that shows part of the wire that is part of the stator winding in 16 is and 24 is a diagram that explains the arrangement of the wires that are part of the stator winding in 16 are.

In the vehicular alternator according to Embodiment 4 of the present invention, the stator includes 70 as it is in 16 is shown: a cylindrical stator core 71 which is made up of a multi-layered core with a number of slots 15a formed in a predetermined pitch extending circumferentially axially is formed; a polyphase stator winding 16 on the stator core 71 is wound; and insulators 19 in each of the slots 15a attached to the polyphase stator winding 16 opposite the stator core 71 electrically isolate.

The stator core 71 comprising: an inner circumferential core portion 73 ; and a cylindrical outer circumferential core portion 76 in press fit over the inner circumferential core section 73 is added. The outer peripheral core section 76 is formed by bonding a plurality of layers of SPCC material and integrating them by laser welding. As it is in the 14 and 15 is explained, the outer peripheral core portion 76 may also be formed by winding a magnetic element in a spiral shape or it may also be tubular.

Next, the winding structure of one phase of the stator winding group becomes 161 with reference to 18 explained in detail. Embodiment 1 was a four-turn winding, but the winding structure of Embodiment 4 is different in that it is divided into two parts.

A phase of the stator winding group 161 is from first to fourth winding subsections 31 to 34 built, each made of a wire 30 are formed. The first winding subsection 31 is by wave winding a wire 30 in every sixth slot from slot # 1 to # 91, leaving it in the slots 15a alternately occupying a first position from the outer circumference side and a second position from the outer circumference side. The second winding subsection 32 is by winding a wire in every sixth slot from slot # 1 to # 91, leaving it in the slots 15a alternately occupying the second position from the outer circumference side and the first position from the outer circumference side. The third winding subsection 33 is by wave winding a wire 30 in every sixth slot from slot # 1 to # 91, leaving it in the slots 15a alternately occupying a third position from the outer circumference side and a fourth position from the outer circumference side. The fourth winding subsection 32 is by wave winding a wire 30 in every sixth slot from slot # 1 to # 91, putting it in the slot 15a alternately the fourth position from the side of the outer circumference and the third. po Position occupied from the side of the outer circumference, formed. The wires 30 are arranged so that they are in each slot 15a Aligned with the longitudinal direction of their rectangular cross-sections aligned in the radial direction in a series of four wires together.

At a first end of the stator core 71 are a first end section 31a of the first winding subsection 31 extending from slot # 1 and a second end portion 33b of the third winding subsection 33 , which extends from slot no. 91, connected and in addition are a first end portion 33a of the third winding subsection 33 extending from slot # 1 and a second end portion 31b of the first winding subsection 31 which extends from slot No. 91, connected to form two turns of winding.

At a second end of the stator core 71 are a first end section 32a of the second winding subsection 32 extending from slot # 1 and a second end portion 34b of the fourth winding subsection 34 , which extends from slot no. 91, connected and in addition are a first end portion 34a of the fourth winding subsection 34 extending from slot # 1 and a second end portion 32b of the winding subsection 32 which extends from slot No. 91, connected to form two turns of winding.

In addition, a section of the wire 30 the second winding subsection 32 located at the first end of the stator core 15 out of the slots 61 and 67 extends, cut open and a section of the wire 30 of the first winding subsection 31 located at the first end of the stator core 15 extending from the slots Nos. 67 and 73 is also cut open. A first cut end 31c of the first winding subsection 31 and a first cut end 32c of the second winding subsection 32 are connected to a phase of the stator winding group 161 with four rounds, with the first to fourth winding subsections 31 to 34 are connected in series.

In addition, the connecting portion between the first cut end 31c of the first winding subsection 31 and the first cut end 32c of the second winding subsection 32 a bridge connection portion, a second cut end 31d of the first winding subsection 31 and a second cut end 32d of the second winding subsection 32 become a connection line (O) or a neutral connection line (N).

In total, six phases will be connected to stator winding groups 161 equally by displacing the slots 15a into which the wires 30 are wound, each time formed around a slot. Then, the three phases of each stator winding group become 161 as it is in 4 is shown connected in star connection to the two groups of the three-phase stator winding sections 160 and each of the three-phase stator winding sections 160 comes with its own rectifier 12 connected. The rectifier 12 are connected in parallel so that the respective DC outputs are combined.

Next is the mounting of the stand 70 explained in detail.

First, as it is in 19 is shown, twelve long wires 30 bent simultaneously in the same plane to form a flash. Then a wire group 35A as they are in the 21 (a) and 21 (b) is shown by progressive folding of the wire at right angles, as indicated by the arrow in 20 is prepared using a device. In addition, a wire group 35B , comprising bridge connections and guide lines, prepared as described in the 22 (a) and 22 (b) is shown.

As it is in 23 is shown, every wire becomes 30 formed by bending into a planar pattern in which straight sections 30b connected by turning sections 30a in a division of six slots (6P) are strung together. Adjacent straight sections 30b are above the turnaround sections 30a by a distance equal to the width (W) of the wires 30 added. The wire groups 35A and 35B are constructed by arranging six pairs of wires so that they are offset from each other at a pitch of one slot, with each pair of wires consisting of two wires 30 which are formed in the above pattern and are offset by a pitch of six slots and are arranged such that the straight portions 30b overlap each other as it is in 24 is shown. Six end sections of the wires 30 each extend from first and second sides at first and second ends of the wire groups 35A and 35B outward. Furthermore, the turning sections 30a arranged so that they are on the first and second side portion of the wire groups 35A and 35B Row in rows.

A cuboid base core 36 will, as it is in the 25 (a) and 25 (b) by laminating a predetermined number of sheets of SPCC material having trapezoidal slots 36a are formed at a predetermined pitch (an electrical angle of 30 °), and laser welding is prepared at an outer portion thereof.

As it is in 26 (a) is shown, a strip of base insulators 72 on the slots 36a of the base core 36 placed and then how it is in the 26 (b) to 26 (d) is shown, the straight sections 30b the two wire groups 35A and 35B in each of the slots 36a introduced. During this insertion, connecting sections become 72a the basic insulators 72 between the slots 36 cut through, causing the insulators 19 be formed and then the straight sections 30b the two wire groups 35A and 35B so absorbed that four of the straight sections 30b within each slot 36a string together and through the insulators 19 opposite the base core 36 are isolated. 27 shows a plan view of the entire stator core in this state.

As it is in 28 (a) is shown next, the cuboid base core 36 with the introduced wire groups 35A and 35B rolled into a cylindrical shape, its ends brought into abutment and joined together to form an abutment section 77 to form and a cylindrical inner peripheral core section 73 is achieved as he in 28 (b) is shown. At this time, a width P2 of the opening portions 15b the slots 15a on the inner peripheral core section 73 smaller than a width P1 of the slots 36a of the cuboid base core 36 , In addition, the base core 36 Be prepared before bending by first bending only the ends, so that when the ends of the base core 36 good roundness of the inner peripheral core section 73 is achieved and even at the contact sections.

The end sections of each wire 30 are connected to the stator winding groups 161 on the basis of the interconnection, which in 18 is shown. Then, the cylindrical outer circumferential core portion becomes 76 made of a number of layers of bonded SPCC material integrated by laser welding, press-fitted over the inner peripheral core section 73 led to the stand 70 to achieve. As it is in 29 are shown, the axial dimensions of the outer peripheral core portion 76 moreover, smaller than the axial dimensions of the inner peripheral core portion 73 to step sections 78 at both edge portions on the outer periphery of the stator core 71 to build.

Because the thickness of the plates in the outer circumferential core portion 76 0.15 mm and the thickness of the plates of the inner peripheral core section 73 0.35 mm, the thickness of the plates is in the outer circumferential core section 76 smaller than the thickness of the plates of the inner peripheral core portion 73 ,

According to Embodiment 4, the process of mounting the stator winding 70 Compared with the conventional art, greatly improved, in which a plurality of conductor segments 305 one after another must be inserted into the slots, by rolling the cuboid base core 36 in a cylindrical shape, with the straight sections 30b the two wire groups 35A and 35B in the slots 36a of the base core 36 are picked up and push on the ends of the base core 36 and welding together.

The rigidity of the stator core 71 is formed by forming the inner peripheral core portion 73 by bending the base core 36 in a cylindrical shape and then press-fitting the inner peripheral core portion 73 in the outer peripheral core section 76 elevated. Before the inner circumferential core section 73 in the outer peripheral core section 76 is introduced, the outer diameter dimensions of the inner peripheral core portion 73 slightly larger than the inner diameter dimensions of the outer peripheral core portion 76 so that the shape of the inner peripheral core section 73 through the outer circumferential core portion 76 by the press-fitting of the outer peripheral core portion 76 is limited, thereby allowing the degree of roundness of the inner peripheral core portion 73 to increase.

Because the investment section 77 in one of the teeth 51 is arranged, the cuboid base core 36 be rolled into a cylindrical shape, with the straight sections 30b the two wire groups 35A and 35B in the slots 36a of the base core 36 are picked up and can without damaging the wires 30 the two wire groups 35A and 35B be connected by welding during the welding process.

Since the radial thickness of the inner peripheral core portion 73 (the part of the core back 50 of the stator core 71 is) smaller than the radial thickness of the outer peripheral core portion 76 (which is also part of the core back 50 of the stator core 71 forms) the base core 36 be reliably converted into a cylinder in this embodiment. The strength of this inner peripheral core section 73 is through the outer peripheral core section 76 increased and the inner peripheral core section 73 is at the investment section 77 firmly connected, thereby allowing the magnetic volume resistance at the contact section 77 to keep to a minimum.

In addition, the mainly magnetic passage is in the circumferential direction of the stator core 71 on the inside of the stator core 71 near the runner 7 which is the magnetic field source and in that the thickness of the core back portion of the inner peripheral core portion is made larger than the thickness of the core back portion of the outer the core core portion, the magnetic passage is mainly arranged in the inner peripheral core portion, whereby the effects of the magnetoresistance due to gaps between the outer peripheral surface of the inner peripheral core portion and the inner peripheral surface of the outer peripheral core portion are minimized.

Because the slots 36a of the base core 36 are trapezoidal and widen in the direction of the opening portions and the circumferential width dimensions of the slots 15a between the teeth 51 of the stand 70 have generally the same dimensions as the circumferential dimensions of the straight sections 30b , the straight sections collide 30b the wire groups 35A and 35B not with the tooth ends and can be introduced evenly and the teeth 51 and the straight sections 30b are prevented from being pressed together and deforming each other during the baseline 36 is bent.

Both axial end surfaces 36A and 36B of the base core are as a result of the deformation of the SPCC material during bending of the base core 36 slightly curved, but in this embodiment, the many layers of SPCC material by welding sections 75 , which extend axially in a number of places, firmly connected, whereby the strength of the base core 36 is increased and bulges are suppressed.

In addition, these weld sections need 75 not equally spaced and they may also be divided in an axial direction.

In the above embodiment, step portions are 78 on both edge portions on the outer periphery of the stator core 71 trained and these stages sections 78 can be brought into engagement with end surfaces of the front half 1 and the rear half 2.

As the thickness of the plates in the outer circumferential core section 76 Further, 0.15 mm and the thickness of the plates of the inner peripheral core section 73 0.35 mm, is the outer circumferential core portion 76 formed by joining steel material with a thin plate thickness, whereby the generation of eddy currents in the outer circumferential core portion 76 suppressed and the output power of the alternator can be improved.

Embodiment 5

30 is a partial cross section of embodiment 5 of the present invention. Embodiment 5 is the same as Embodiment 4 except for the fact that the thickness of the plates in the outer circumferential core portion 79 0.5 mm, wherein the thickness of the plates in the outer peripheral portion is increased from 0.15 mm to 0.5 mm. The strength of the outer peripheral core section 79 is increased in proportion to increasing the thickness of the plates and at the abutment section 77 the base core is more firmly connected, thereby allowing the magnetic volume resistance at the abutment portion 77 even lower.

Embodiment 6

31 is an overall perspective of a stand 80 according to embodiment 6 of the present invention and 32 is a cross section of the stator core 81 of the stand 80 out 31 , A separate gap section 83 which extends radially is at a location in the outer circumferential core portion 82 of the stator core 81 educated. In the embodiments 4 and 5 became a cylindrical outer peripheral core 76 or 79 over the outside of a cylindrical inner peripheral core section 73 In the embodiment 6, the inner peripheral core portion is pressed 73 and the outer circumferential core portion 32 by on far the outer peripheral core portion 32 , that at the split section 83 is open, and radially inserting the outer peripheral core portion 73 joined together, whereby the assembly process is improved. After integrating, the cylindrical shape of the inner peripheral core portion becomes 73 by the elasticity of the outer peripheral core portion 82 maintained.

Embodiment 7

33 is a cross section of a stator core 84 according to embodiment 7 of the present invention. This stator core 84 includes an inner circumferential core portion 85 in which a radial dimension of a core back section 85a 2.6 mm and an outer circumferential core section 86 with a thickness of 1 mm. Notched sections 87 are in the bottom surfaces of the slots 15a of the inner peripheral core portion 85 educated.

In this embodiment, the inner peripheral core portion is 85 by bending a base core 88 , as in 34 shown formed in a cylindrical shape. The thickness of a core back section 85a of the inner peripheral core portion 85 is larger than the thickness of a core back portion 36a of the outer peripheral core portion 86 (the thickness of the outer peripheral core portion 86 ), which requires a great force for bending deformation, but by providing the notched portions 87 the bending load is reduced. In addition, those through the notched sections 87 closed and eliminated in the base core spaces as a result of the bending process.

Embodiment 8

35 is a cross section of a stator core 90 according to embodiment 8 of the present invention and 36 is a partial enlargement of the stator core 90 out 35 , In each of the above embodiments, the groups of winding groups having a phase difference of 30 ° were wound on the stator core, but in this embodiment, the groups of winding groups having a phase difference of 36 ° were applied to the stator core 90 wound.

In embodiment 8, teeth change 92 and 93 in an inner circumferential core section 91 between different circumferential width dimensions, the pitch between centerlines extending radially from adjacent opening portions 94 and 95 extend repeatedly between an electrical angle of 24 ° and an electrical angle of 36 °. Furthermore, the contact section 77 of the inner peripheral core portion 71 in one of the broad teeth 93 arranged.

Since the inner peripheral core section 91 teeth 92 and 93 having different circumferential width dimensions and the abutment section 77 of the inner peripheral core portion 91 in one of the broad teeth 93 is arranged, the strength of the teeth 93 even in the investment section 77 high, which makes it possible to reliably install the winding in the slots. Since the circumferential width dimensions are different, the pitch is between centerlines extending from the opening portions 15b the slots 15 Radially extend, moreover, unevenly, whereby disturbances and fluctuations of the generated voltage can be reduced.

Embodiment 9

37 is a partial cross section of a stator core 200 according to embodiment 9 of the present invention and 38 is a partial enlargement of the stator core 200 out 37 , The windings are omitted in these figures.

The stator core 200 according to Embodiment 9 of the present invention is made of an inner peripheral core portion 201 which is divided into two parts and a cylindrical outer circumferential core portion 203 making the inner circumference core section 201 surrounds, built up. groove sections 204 which extend axially in a uniform pitch in the circumferential direction are in an inner wall surface of the outer peripheral core portion 203 educated. End sections of the teeth 207 of the inner peripheral core portion 201 be in these groove sections 204 introduced. projections 206 are in the groove sections 204 trained and wells 204 in the projections 206 are fit on the end sections of the teeth 207 educated.

In the embodiment 9, a stator winding (not shown) is formed on the inner peripheral core portion 201 and then mounting the stand by inserting the outer peripheral core portion 203 in the inner peripheral core section 201 completed from an axial direction, so that the projections 206 with the wells 205 get in touch.

unequal each of the other embodiments above, the assembly is simplified because of this embodiment dividing surfaces only in the circumferential direction. In this embodiment, end portions neighboring teeth connected to a radially inner portion, which is the output power so to speak can reduce radially inner sections above Be cut off to opening sections after mounting the stand to build.

Embodiment 10

39 is a perspective of a stand 100 according to embodiment 10 of the present invention, 40 is a cross section of a stator core 101 of the stand 100 out 39 , In the embodiment 10, the stator core 101 only one investment section 102 and does not have a circumferential core portion compared with the stator core used in the embodiments 4 to 9 was described on. That is, in the stator core, in the embodiments 4 to 9 has been described, the core back of the stator core consists of two different sections, which are the core back portion of the inner peripheral core portion and the outer peripheral core portion. In this embodiment, the thickness of a core spine is 103 of the base core 3.6 mm, on the outer peripheral core portion described in Embodiments 4 to 9 is omitted, and the core back 103 of the stator core 101 is inseparable and integral. The investment section 102 is inside the teeth 93 formed with large circumferential widths alike as in the embodiment 8. Embodiment 10 is the same as Embodiment 4 to 8 with respect to the other components of the stator winding, etc.

According to Embodiment 10, the operation of attaching the outer peripheral core portion via the inner peripheral core portion is omitted. Moreover, it is difficult to improve the degree of inner diameter roundness of the stator because the bending load required to bend the base core into a cylindrical shape is increased, but this does not pose a great problem when the inner diameter portion of the stator is machined becomes. Further, it does not occur that the output power by gaps between the inner peripheral core portion and the outer peripheral core portion is reduced, and magnetic noise is increased by lowering the strength of the stator core.

at Any of the above embodiments may about that beyond after insertion of the winding groups into the slots of the cuboid core, a processing device from a radial direction against the tooth ends are pressed to they plastically deform while keeping the opening sections of the slots to narrow down.

at Each of the above embodiments will be the insulators before insertion the wire groups in the stator core first be placed on the core side or become long insulators on the cuboid Arranged core and introduced the wire groups from above, so that the insulators are taken up in the slots at the same time, but the insulators can also before that on the sections of wire groups that are in the slots are to be taken up, wound up and together with the wire groups inserted into the slots become. additionally can the sections of the wire groups that take up in the slots are to be doused in advance with an insulating resin. In this Case becomes mass productivity significantly improved.

at Any of the above embodiments may a ring-shaped Core prepared by rolling up a parallelepipedic core in an outer core introduced and then be integrated by shrinking.

As it explained above was included in an alternator according to one aspect of the present invention Invention the polyphase stator winding a number of winding sections in which long wires are so are wound in the slots at intervals of a predetermined Number of slots alternately an inner layer and an outer layer occupy in a slot depth direction, the wires outside the slots on axial end surfaces of the stator core rewound are and the stator core is provided with abutment portions extending axially, so that the stator core by connecting the ends of the stator core the abutment sections an annular Get shape. Therefore, the winding is made of long continuous wires built, which allows the degree of order of the coil ends and the space factor of the winding to raise in the slots and the production of the stand to facilitate.

at the alternator according to a In the form of this invention, the stator core may be divided into arcuate sections Core sections be constructed. This allows the stand through Introduce divided core sections from a radial direction relative to a polyphase stator winding be prepared, thereby improving the production of the stand becomes.

at the alternator according to a In another form of this invention, the stator core may be inseparable and integral be. Thereby, the process of fitting the outer peripheral core portion over the Inner circumferential core portion are dispensed with. In addition, it is difficult to improve the degree of internal diameter roundness of the stand, because the required bending load to bend the base core into a cylindrical one Shape increased is, but this is not big Problem is when the inner diameter portion of the stator in a processing step is processed. Further, does not occur that the output power through gaps between the inner peripheral core section and the outer circumferential core portion is reduced and magnetic interference by lowering the strength of the stator core elevated become.

at the alternator according to a Another aspect of this invention includes the multiphase stator winding a number of winding sections in which long wires are so are wound in the slots at intervals of a predetermined Number of slots alternately an inner layer and an outer layer occupy in a slot depth direction, the wires outside the slots on axial end surfaces of the stator core rewound are and the stator core comprising: an inner circumferential core portion which is toothed on one Side near the runner is provided, with the teeth define the slots; and an outer peripheral core portion that extends over a Outer peripheral side of the inner peripheral core portion. This is the winding from long continuous wires built, which allows is the order of the coil ends and the space factor of the winding to raise in the slots and the inner peripheral core portion and the outer circumferential core portion can pass through Introduce of the inner peripheral core portion in the outer circumferential core portion an axial direction are integrated, whereby the production of the stand is relieved.

In the alternator according to one form of this invention, the inner circumferential core portion may be provided with abutting portions so that the inner circumferential core portion is annularly formed by connecting the ends of the inner circumferential core portion to the abutting portions. Thereby, a coil group can be easily inserted into the slots of the inner peripheral core portion in a straight state, whereby the Inserting operation is facilitated and the force required to bend the inner peripheral core portion is also reduced, which simplifies the manufacture of the stator. The strength of the stator is improved and the occurrence of gaps on the abutment portion is reduced by the outer circumferential core portion, thereby reducing the magnetic resistance and improving the output performance.

at the alternator according to a another form of this invention may be only one of the abutment sections be provided. Therefore, the strength of the inner peripheral core portion becomes elevated, whereby the occurrence of electromagnetic interference is reduced. Further The magnetic resistance is reduced and the output power improved, because there is only one abutment section at which form gaps can.

at the alternator according to another In another form of this invention, the outer circumferential core portion may be provided with be provided a gap portion, so that a radius of curvature of the outer peripheral core portion be increased by expanding the gap portion in a circumferential direction can. Thereby, the process of fitting the outer peripheral core portion over the Inner peripheral core section can be improved.

at the alternator according to a In another form of this invention, at least the inner circumferential core portion or the outer circumferential core portion by a variety of plate-shaped be formed of magnetic elements. Therefore, the generation of eddy currents in the outer peripheral core portion repressed and the output power can be improved.

at the alternator according to a Another form of this invention may be a plate thickness of the plate-shaped magnetic Elements of the outer peripheral core section thinner its as a plate thickness the plate-shaped magnetic elements of the inner peripheral core section. Therefore, will the generation of eddy currents in the outer peripheral core section further suppressed and the output power increases.

at the alternator according to another Another form of this invention may be a plate thickness of disc-shaped magnetic element of the outer peripheral core portion be thicker than a plate thickness of the plate-shaped magnetic element of the inner peripheral core portion. This will the strength of the stand overall mainly through the outer circumferential core portion provided, thereby enabling will, the strength the plates of the plate-shaped magnetic element of the inner peripheral core portion thinner shape.

at the alternator according to a Form of this invention, the outer peripheral core portion a multi-layered structure, in which the plate-shaped magnetic Elements become a spiral Shape are wrapped. Thereby, the productivity of the outer peripheral core portion becomes improved.

at the alternator according to a another embodiment of this invention, the outer peripheral core portion have an integral tubular shape. Therefore, a highly rigid stand to be provided.

at the alternator according to another another embodiment of this invention the axial dimensions of the outer circumferential core portion smaller than the axial dimension of the inner peripheral core portion. Therefore, the stand with the bracket can be engaged without a separate Perform operation, around notches in the outer peripheral core sections to cut.

at the alternator according to a Form of this invention is a radial thickness dimension of the outer peripheral core portion smaller than a radial thickness dimension of the inner peripheral core portion. Therefore, you can Reductions in the output power can be suppressed.

at the alternator according to a Another form of this invention may have a radial thickness dimension of the outer peripheral core portion to be taller as a radial thickness dimension of the inner peripheral core portion. Therefore, the inner peripheral core portion becomes the high-rigidity outer peripheral core portion supported whereby the generation of electromagnetic interference is suppressed and the roundness of the inner peripheral core portion can be further improved.

at the alternator according to another another embodiment of this invention the inner circumferential core portion and the outer circumferential core portion be integrated with a press fit. Therefore, the contact between improves the inner peripheral core portion and the outer peripheral core portion, whereby the magnetic resistance is proportionally reduced.

at the alternator according to a Form of this invention may be the stator core with notch portions be formed to reduce a compressive force in one direction the one radius of curvature reduced. Therefore, the bending process is facilitated.

In the alternator according to another In the form of this invention, the abutment portions may be formed inside the teeth. Therefore, the process of bumping is simplified, and because the patch is aligned with the direction of the main magnetic flux, reductions in the output are suppressed.

at the alternator according to another In another form of this invention, the stator core may be provided with teeth be, which have different Umfangsbreitendimensionen and The abutment section may be within the teeth with large circumferential width dimensions be educated. Therefore, the strength of the tooth on the abutment section high, which allows is, the winding reliable to install in the slots. In addition, by varying the circumferential width dimensions the division between centerlines, extending radially from the opening sections the slots extend, unevenly shaped, thereby allowing disorders and to reduce fluctuations in the generated voltage.

Claims (7)

Alternator comprising: a rotor ( 7 ) for forming a north (N) and a south pole (S) alternately around a rotation circumference; and a stand ( 8th ) comprising: a stator core ( 15 ), the runner ( 7 ) surrounds; and a polyphase stator winding ( 16 ) in the stator core ( 15 ), wherein the stator core ( 15 ) with a number of slots ( 15a ) which extend axially in a predetermined pitch in a circumferential direction, characterized in that the multiphase stator winding ( 16 ) a number of winding sections ( 31 - 34 ), in each of which a continuous wire is wound in such a way that it is arranged at intervals of a predetermined number of slots (FIG. 15a ) in the slots ( 15a ) alternately occupies an inner layer and an outer layer in the slot depth direction, the wire ( 30 ) outside the slots ( 15a ) at axial end surfaces of the stator core ( 15 ), and in that the stator core ( 15 ) with a contact section ( 77 . 102 ), which extends axially, so that the stator core ( 15 ) by joining ends of the stator core ( 15 ) assumes an annular shape at the abutment portion. Stand according to Claim 1, in which the stator core ( 15 ) of arcuate split core sections ( 15A ) is composed. Generator according to claim 1 or 2, wherein the stator core ( 101 ) an inseparable integral core spine ( 103 ) having. Generator according to one of Claims 1 to 3, in which only the contact section ( 77 . 102 ) is provided. Generator according to one of Claims 1 to 4, in which the stator core ( 15 . 101 ) and the inner circumferential core portion ( 62 ) each with notch sections ( 87 ) to reduce a compressive force in a direction reducing a radius of curvature. Generator according to one of Claims 1 to 5, in which the abutment section ( 77 . 102 ) within teeth ( 92 . 93 ) is trained. Generator according to Claim 6, in which the stator core ( 15 . 101 ) and the inner circumferential core portion ( 62 ) with teeth ( 92 . 93 ) having different circumferential width dimensions; and the investment section ( 77 . 102 ) within teeth ( 93 ) is formed with large circumferential width dimensions.