Source: https://patents.google.com/patent/DE69816263T2/en
Timestamp: 2020-07-04 18:21:37
Document Index: 41844148

Matched Legal Cases: ['arts 11', 'arts 11', 'art 12', 'arts 11', 'arts 11', 'arts 11', 'art 11', 'art 12', 'arts 11', 'arts 11', 'arts 211', 'arts 211', 'art 211', 'arts 211', 'arts 211', 'arts 221', 'arts 211', 'arts 211', 'arts 221', 'arts 211', 'arts 211']

DE69816263T2 - Method and device for turning u-shaped stator winding heads - Google Patents
Method and device for turning u-shaped stator winding heads
DE69816263T2
DE69816263T2 DE1998616263 DE69816263T DE69816263T2 DE 69816263 T2 DE69816263 T2 DE 69816263T2 DE 1998616263 DE1998616263 DE 1998616263 DE 69816263 T DE69816263 T DE 69816263T DE 69816263 T2 DE69816263 T2 DE 69816263T2
DE1998616263
DE69816263T3 (en
DE69816263D1 (en
Youichi Kariya-city KAMAKURA
Kazutaka Kariya-city MAEDA
Masaru Kariya-city SUGIYAMA
Nobuo Kariya-city SUKO
Makoto Kariya-city TAKAHASHI
2003-08-14 Publication of DE69816263D1 publication Critical patent/DE69816263D1/en
2004-04-07 First worldwide family litigation filed litigation Critical https://patents.darts-ip.com/?family=17674032&utm_source=google_patent&utm_medium=platform_link&utm_campaign=public_patent_search&patent=DE69816263(T2) "Global patent litigation dataset” by Darts-ip is licensed under a Creative Commons Attribution 4.0 International License.
2004-05-13 Publication of DE69816263T2 publication Critical patent/DE69816263T2/en
2007-09-13 Publication of DE69816263T3 publication Critical patent/DE69816263T3/en
238000004804 winding Methods 0.000 title claims description 39
239000004020 conductor Substances 0.000 claims description 60
1. area the invention
The present invention relates to a conductor twisting device for twisting turn sections of U-shaped conductor segments, which are arranged in a plurality of circumferentially arranged slots a stator core are arranged, according to claim 1. In addition The present invention also relates to a method for rotating a Variety of conductor segments according to the claim 9th
As for an alternator of a vehicle a higher one Performance is required, the Resistance of the stator winding become lower and lower in order thereby the length to reduce the magnetic wire.
It is well known that a variety of U-shaped conductor segments each in slots of a stator core be introduced in the same direction and connected together to form a stator winding to form, which then generates the output power of a vehicle AC generator elevated can be like this in the publication according to the international publication number WO 92/06527 (1992) is disclosed. Because the U-shaped conductor segments very regular in this construction can be arranged, the slot space factor and increases its output.
Before the turn portions of the conductor segments are twisted in a manufacturing process of the conventional construction explained above, an annular holder holds 310 the winding sections 301 . 302a . 303a of the conductor segments 301 . 302 . 303 , as in 16 of the present application. There are straight sections 301b . 302b . 303b in twisting tools 311 . 312 introduced that are relative to the annular holder 310 are rotated or rotated in directions opposite to each other and by an angle of T / 2 (where T is a pole pitch angle). As a result, the straight sections 301b . 302b . 303b of the segments 301 . 302 . 303 bent or turned with T / 2, as in 17 is shown.
Because the ring-shaped holder 310 the entire arc sections of the winding sections 301 . 302a . 303a of the segments 301 . 302 . 303 holds, the coil ends become longer than the coil ends that are formed without the annular holder 310 to use. That means the wire length gets longer. If in this conventional method the segments 301 . 302 . 303 The segments are inserted into the slots 301 . 302 . 303 through the ring-shaped holder 310 at the turn sections 301 . 302a . 303a held. The straight sections 301b . 302b . 303b are inserted into the slots, with only the winding sections 301 . 302a . 303a are captured.
In this process, the segments 301 . 302 . 303 only on the winding sections 301 . 302a . 303a (Deflection sections) are held, which are arranged at the end of the stator core and specifically opposite the end from which the segments are inserted into the slots. Therefore, the straight sections 301b . 302b . 303b not be positioned exactly and the segments 301 . 302 . 303 can collide with the slot inner walls, damaging them when the conductor segments are inserted into the slots. As the number of slots increases, the distance between the slots decreases and higher accuracy is required with this method. However, it is difficult to realize such high accuracy with this method.
The present invention has been made Solution of problems developed above and around a procedure and a Device for Manufacture of U-shaped conductor segments to create with the the accuracy when inserting the segments into the slots Stator can be improved.
The present invention aims to achieve this off, one device to create a stator where the damage the segments is reduced and formed at the short winding ends can be.
The present invention also aims from then on to specify a method for manufacturing a stator, possible with the short winding ends are.
According to the conductor twisting device according to the invention does the above object by the features of the claim 1 solved.
Advantageous embodiments of the twisting device according to the invention result itself from the subclaims 2 to 8.
In connection with the method according to the invention the above is used to twist a large number of conductor segments Object achieved by the method steps of claim 9.
Advantageous embodiments of the inventive method result from the subclaims 10 to 15.
The device for solving the above task contains a first turning tool ( 11 ), which has a straight section ( 31b . 32b ) of the U-shaped conductor segments ( 3 . 31 . 32 ) contains a second turning tool ( 12 ) which is the other straight section ( 31c . 32c ) the U-shaped conductor segment ( 3 . 31 . 32 ) and a rotation relative to the first turning tool ( 11 ) and with a circumferential holder ( 16a ), the middle section of the winding sections ( 31a . 32a ) of the U-shaped conductor segments ( 3 . 31 . 32 ) and circumferential movement of the winding or deflection sections ( 31a . 32a ) limits.
If the deflection sections ( 31a . 32a ) are rotated, the circumferential mounting section ( 16a ) only the radial middle sections of the deflection sections ( 31a . 32a ) and only fixed in the circumferential direction. If the straight section ( 31b . 31c . 32b . 32c ) of the U-shaped conductor segments ( 3 . 31 . 32 ) are widened in the circumferential direction, only the middle sections of the deflection sections ( 31a . 32a ) fixed so that the two sides of the deflecting sections can be bent gently or softly in a curved line.
The U-shaped conductor segments ( 3 . 31 . 32 ) contain overlapping conductor segments with different radii of curvature. The first turning tool ( 11 ) and the second turning tool ( 12 ) hold the straight sections ( 31b . 32b ) that extend from opposite sides of the deflection sections ( 31a . 32a ) of the overlapping conductor segments ( 3 . 31 . 32 ) extend from and have different radii. The circumferential holder ( 16a ) limits the circumferential movement of the overlapping deflection sections ( 31a . 32a ) on.
The overlapping deflection sections ( 31a . 32a ) are rotated at the same time.
There are holding holes ( 111 . 112 . 121 . 122 ) in the first turning tool ( 11 ) and in the second turning tool ( 12 ) in the axial direction thereof to form the straight portions ( 31b . 31c . 32b . 32c ) of the conductor segments ( 3 . 31 . 32 ) to hold onto.
There can be as many holding holes ( 111 . 112 . 121 . 122 ) can be provided according to a number corresponding to the number of slots ( 2 ) corresponds to and at equal intervals in the circumferential direction.
One method to achieve the above object comprises a fixing step for inserting the straight sections ( 31b . 31c . 32b . 32c ) of the U-shaped conductor segments ( 3 . 31 . 32 ) in the holding holes ( 111 . 112 . 121 . 122 ), a first turning tool ( 11 ) and a second turning tool ( 12 ), a rotating section holding step according to holding only a middle section of the deflecting sections ( 31a . 32a ) to the circumferential movement of the first and the second turning tool ( 11 . 12 ), and a bending or twisting step according to a twisting of the first turning tool ( 11 ) relative to the second turning tool ( 12 ).
If the deflection sections ( 31a . 32a ) are bent or twisted, the circumferential holder ( 16a ) the deflection sections ( 31a . 32a ) only circumferentially fixed and only on the radial middle section of the deflection sections ( 31a . 32a ).
If the straight sections ( 31b . 31c . 32b . 32c ) of the U-shaped conductor segments ( 3 . 31 . 32 ) are expanded circumferentially, only the middle section of the deflection sections ( 31a . 32a ) fixed so that the opposite sides of the deflection sections ( 31a . 32a ) can be shaped in a smooth or soft curve.
The large number of conductor segments ( 3 . 31 . 32 ) are aligned in the circumferential direction. The multitude of deflection sections ( 31a . 32a ) with a different radius of curvature can overlap.
The deflection sections ( 31a . 32a ) the large number of conductor segments ( 3 . 31 . 32 ) are rotated at the same time.
The method for solving the above-mentioned object further comprises a holding step according to holding the U-shaped conductor segments ( 3 . 31 . 32 ), an insertion step for guiding and inserting the straight sections ( 31b . 31c . 32b . 32c ) from the edge sections ( 31d . 31e . 32d . 32e ) into the slots ( 2 ), and a press-fastening step according to producing a press fit of the U-shaped conductor segments ( 3 . 31 . 32 ) in the slots ( 2 ) on the deflection sections ( 31a . 32a ) the same.
Since the conductor segments are guided into the slots at the sections adjacent to the slots, a higher positioning accuracy can be achieved compared to the winding sections which are only on the deflection sections ( 31a . 32a ) are supported. As a result, the conductor segments can be prevented from colliding with the inner walls of the slots, thereby preventing damage.
The introductory step restricts the movement of the deflection sections ( 31a . 32a ) of the U-shaped conductor segments ( 3 . 31 . 32 ) in the circumferential directions of the stator core ( 1 ).
The press mounting step includes a step of restricting the movement of the deflecting sections ( 31a . 32a ) in the middle of the same.
The conductor segments ( 3 . 31 . 32 ) are prevented from shifting in the circumferential direction when they enter the slots ( 2 ) are inserted so that the same can be prevented with the inner walls of the slots ( 2 ) to collide.
1 Figure 3 is a perspective view of a stator core, insulators, and segments of a stator according to a preferred embodiment of the invention;
2 shows a perspective view of the segments before rotation;
3 is a perspective view of a Twisting tool for the deflection sections;
4 shows a cross-sectional view of the turning tool for the turn portions;
7 Fig. 12 is a schematic view illustrating a step of taking the segments out of the twisting tool;
8th Fig. 2 is a schematic view illustrating the segments held by an outside holder and an inside holder;
9 Figure 12 is a schematic view illustrating a step in accordance with the insertion of edge or edge portions of the segments into the slots;
10 Fig. 11 is a schematic view illustrating a step according to a return movement of the conductor segments from an outside holder and an inside holder;
11 Fig. 12 is a schematic view showing a step according to the insertion of the segments into the slots;
12 Fig. 4 is a partial cross-sectional view of the stator;
14 Fig. 3 shows a flow chart illustrating the steps in the manufacture of the stator;
15 Fig. 11 is a schematic view illustrating a modification of the step of inserting the segments into the slots; and
16 and 17 each show schematic views illustrating a conventional device for rotating the winding or deflection sections.
A preferred embodiment the present invention will now be described in detail on the attached Described drawings.
A method and an apparatus for manufacturing an alternator stator of a vehicle according to a first embodiment of the present invention are described in detail with reference to FIGS 1 - 14 described. 1 shows a perspective view of a stator core, insulators and segments used in the manufacture of a stator.
A variety of U-shaped conductor segments 3 (hereinafter referred to as "the conductor segments") are each in a plurality of slots 2 inserted, which are formed on a cylindrical stator core in the circumferential direction, and the edge portions of the segments are connected to form a stator winding.
A copper wire with a rectangular cross-section is cut into a segment of a prescribed length, which is bent around the U-shaped segments 3 to build. As in 2 there are two types of U-shaped segments 3 , a large segment and a small segment. The deflection section 32a of the big segment 32 encloses the deflection section 31a of the small segment 31 , The edge sections 32d . 32e of the big segment 32 have conical surfaces that fall from the outside to the inside, and the edge sections 31d . 31e of the small segment 31 have conical surfaces that fall from the inside to the outside.
3 is a perspective view of a turning tool for the deflection sections of the segments 3 , 4 shows a cross-sectional view of the turning tool for the deflection sections. The turning tool 10 contains an inside twist part for the deflection sections 11 , an outside twist 12 , a deflection mechanism 13 . 14 for redirecting or reversing the inside and outside twisting parts 11 . 12 , a controller 15 , a segment presser 16 and a segment pusher 17 ,
The segment holes 111 . 112 for the straight sections 31b . 32b of the segments 3 that are inserted and held thereon are side by side radially in the inside twisting tool 11 educated. There are exactly as many (e.g. 36) segment holes 111 . 112 like the number which of the number of slots 2 corresponds, formed in the circumferential direction at equal intervals. In other words, there are 36 segment holes 111 . 112 formed in a circle at equal intervals. The segment holes 121 . 122 of the outside twisting tool 12 are the same as the holes 111 . 112 of the inside twisting tool 11 , As a result, there are four segment holes 111 . 112 . 121 . 122 in a radial line from the inside turning parts 11 to the outside turning part 12 educated.
A pair of small and large curved segments 3 , in the 3 are shown simultaneously in the segment holes 111 . 112 . 121 . 122 the inside and outside twisted parts 11 . 12 introduced.
After the segments 31 . 32 in all the segment holes 111 . 112 . 121 . 122 have been introduced, the ring presser 16 in contact with the deflecting section 32a of the big segment 32 from the upper side of the inside and outside twisting parts 11 . 12 brought. Because the deflection section 31a of the small segment 31 through the section 32a of the big segment 32 enclosed is the deflection section 31a of the small segment 31 through the deflection section 32a of the big segment 32 printed down. This will make the small and large segments 3 prevented from coming out of the segment holes 111 . 112 . 121 . 122 to slide outwards or out.
5 shows a partial cross-sectional view of the segments inserted into the segment holes and the segment presser. The segment press 16 contains cylindrical protrusions 16a that in the axial direction between adjacent deflection sections 31a . 32a of the small and large segments 3 are introduced. The lead 16a is at the radial central section of the deflection sections 31a . 32a arranged around the middle of the deflecting sections 31a . 32a between the circumferentially opposite sides thereof, thereby restricting the circumferential movement of the central portions.
The inside and outside twisted parts 11 and 12 are through the twist mechanism 13 . 14 rotated, each by the controller 15 to be controlled. The inside twisted part 11 turns counterclockwise as seen from a section above the turning tool 10 of the rotating section, and the outside twisting part 12 rotates clockwise by an angle T / 2 (ie one and a half of a slot division). Thus the deflection sections 31a . 32a of the small and large segments 3 twisted in the circumferential direction.
If the deflection sections 31a . 32a the lead holds 16a the deflection sections 31a . 32a not, except on the radial middle section of the deflection sections 31a . 32a in the circumferential direction. If the straight sections 31b . 31c . 32b . 32c of the small and large segments 3 in the circumferential direction in the step of twisting the side of the deflecting portions 31a . 32a to be expanded is only the middle of the deflection sections 31a . 32a fixed so that both sides of the deflection sections can be bent smoothly and smoothly in a curved line. Thus, the small and large segments then have 3 twisted deflection sections 31a and 32a how this in 6 is shown and are created in this way. It is important that both twisted parts 11 and 12 be rotated relative to each other. Therefore, one of the twisted parts 11 . 12 be twisted while the other is fixed.
There are now steps according to pulling out the small and large segments 3 with the twisted deflection sections 31a . 32a from the twisting tool 10 out and inserting them into the slots 2 of the stator core described below.
7 shows a schematic view illustrating a step according to a pulling out of the twisted segments from the twisting tool and 8th Fig. 12 is a schematic view illustrating the segments held by an outside holder and an inside holder. The segment pusher 17 is under the inside and outside twisted 11 and 12 arranged. If the segment pusher 17 is raised, the edge sections 31d . 31e . 32d . 32e of the small and large segments 3 by the twisting tool 10 were twisted, pushed upward in the axial direction. As a result, the straight sections 31b . 31c . 32b . 32c of the segments 31 . 32 partly from the segment holes 111 . 112 . 121 . 122 pulled out. The outside and inside holders 21 and 22 hold the pulled out sections of the straight sections 31b . 31c . 32b . 32c firmly.
The outside holder 31 has thin tooth parts 211 and a tooth holder 212 , The tooth holder 212 is a cylindrical part with 36 rectangular through holes 212a which extend radially around the 36 slots of the stator core 1 correspond to. Each of the tooth parts 211 has a base section 211 with a rectangular cross section, and a tooth 211b extending from one side of the base section 211 extends radially inward. The cross section of the base section 211 corresponds to the shape of the holder 212a , The base section 211 of the tooth part 211 gets into one of the holes 212a introduced. The tooth parts 211 can be moved in the radial direction by the drive mechanism.
The inside holder 22 contains a variety of fan-shaped inside holder parts 211 and an extruder 222 which is the inside holder 221 extruded in the radial outward direction. The radially inner end of the holder parts 221 has a surface that tapers from top to bottom. The extruder 222 has a tapered lower section that points downwards.
The tooth parts 211 are moved radially inwards to the tooth sections 211b between the straight sections 31b . 31c . 32b . 32c that are adjacent to each other, introduce themselves from the segment holes 111 . 112 . 121 . 122 extend from. The edge or edge of the tooth section 211b is conical, so that it can easily be between the straight sections 31b . 31c . 32b . 32c can be introduced.
The straight sections 31b . 31c . 32b . 32c be between the inside surface 211d from a tooth section 211b and the outside surface 211e of the adjacent tooth section 211b held. Because the segments 3 be pushed a length in the axial direction before passing through the tooth parts 211 the straight sections can be held 31b . 31c . 32b . 32c of the segments 3 held at portions that are the same length lower than the top ends thereof.
The extruder 222 can go up and move down using the drive mechanism. The inside surface of the inside holder 221 is in contact with the conical surface of the extruder 222 , Therefore, the holder parts 221 in the radial direction outwards due to the downward movement of the extruder 222 moves, it becomes the outside surface 221a of the inside holder 221 in contact with the innermost straight section 32b of the four segments 3 brought, which are aligned in the radial direction, creating the straight sections 31b . 31c . 32b . 32c be pushed radially outwards.
On the other hand, an outside holding surface engages 211c of the tooth section 211b to the outermost straight section 32c of the four segments 3 when the tooth parts 211 move inward, creating the straight sections 31b . 31c . 32b . 32c be pushed radially inwards. It will therefore align the four segments 3 through the outside surface 221a of the inside holder 221 and through the outside holding surface 211c of the outside holder 21 held in the radial direction.
The outside holder 21 and the inside holder 22 keep the straight sections 31b . 31c . 32b . 32c and move up to the segments 3 from the twisting tool 10 pull it out. If the outside holder 21 and the inside holder 22 are moved upward, the inside holder 22 and a support plate 213 of the outside holder 21 through the drive mechanism 214 moved synchronously with each other.
9 shows a schematic view showing a step according to the introduction of the segments into the slots of the stator core 1 illustrated from the edge of the same; 10 12 is a schematic view illustrating a step of removing the outside holder and the inside holder from the segments; and 11 Fig. 11 is a schematic view showing a step of making a press fit or press fit of the segments in the slots.
As in 9 is shown is the stator core 1 with isolators 4 equipped and is in an assembly tool 20 used. The stator core 1 is positioned so that each of the slots is arranged to correspond to a corresponding one of the segments 3 opposed by the outside holder 21 and the inside holder 22 being held. The outside holder 21 and the inside bracket 22 are from a section above the stator core 1 lowered from the segments 3 into the slots 2 from the edge sections 31d . 31e . 32d . 32e introduce the same.
The outside holder will hold during this step 21 and the inside bracket 22 the straight sections 31b . 31c . 32b . 32c of the segments 3 at the bottom section along the length of the segment pusher 17 was raised. Because the straight sections 31b . 31c . 32b . 32c at the position near the edge portions 31d . 31e . 32d . 32e can be maintained, a high accuracy can be ensured, compared to the device for holding only the winding or deflection sections 31a . 32a , In other words, the holders form 21 . 22 not only holders for holding the plurality of segments for making a movement, but also form guides for guiding the edge portions of the segments to the openings of the slots 2 out. In the foregoing description of the present invention, the outermost straight section has 32c and the innermost 32b of the four segments 3 , which are arranged in a radial line, a conically shaped or tapered surface. Therefore, the four segments 3 smooth into the slots 2 be inserted.
If the straight sections 31b . 31c . 32b . 32c of the segments 3 into the slots 2 are inserted, both circumferential sides of the reverse sections 31a . 32a through the ledges 16a of the segment presser 16 supported. Therefore, the segments can be prevented 3 shift in the circumferential direction so that the positioning accuracy can be improved.
As in 10 is shown after the straight sections 31b . 31c . 32b . 32c of the segments 3 into the slots 2 the outside holder 21 moved outward and the inside holder 22 are moved up to the segments 3 to free. As in 11 is shown, a segment press unit 23 lowered so that the segment press 16 the deflection sections 31a . 32a of the segments 3 presses down. It will be the segments 3 according to an interference fit in the slots 2 anchored to form winding ends of a prescribed height.
If the segments 3 according to a press connection or a press fit into the slots 2 have been fitted, the deflection sections 32a of the big segments 32 through the segment press 16 pressed down. The tabs 16a extending from the bottom of the segment press 16 Extend downward, holding the middle sections of the reverse sections 31a . 32a to the circumferential displacement of the segments 3 to restrict. This prevents the projections 16a that the segments 3 with the inner walls of the slots 2 collide and be damaged.
The straight sections 31b . 31c . 32b . 32c of the four radially aligned segments 3 are in the slots 2 introduced so that four segments can be aligned in the slot as in 12 is shown.
After the segments 3 in all the slots 2 have been arranged, the straight sections 31b . 31c . 32b . 32c of the segments 3 coming out of the slots 2 extend out, twisted alternately in opposite directions and indeed in each layer and in each case at an angle of T / 2 (ie by a 1½ slot divisions) with the aid of an edge twisting tool (not shown). In other words, the segments 3 rotated by T / 2 in the first and third layers from the innermost layer in a circumferential direction, and the segments 3 the second and fourth layers are twisted or rotated by T / 2 in the other circumferential direction. The direction of rotation is the same for each layer, namely around the stator core 1 around and the segments in the same layer are inclined in the same direction.
After the straight sections 31b . 31c . 32b . 32c from each of the segments 3 has been twisted in the circumferential direction, insulating films, the edge portions 31d . 31e . 32d . 32e of the segments 3 cover, peeled off after the stator core with the twisted segments has been removed, leaving the edge portions 31d . 31e . 32d . 32e the same are immersed in a strong alkaline solution. After that, the edge sections 32d in the first layer from the innermost side and the edge sections 31d electrically interconnected in the second layer, and the sections 31e in the third layer and the edge sections 32e in the fourth layer are connected by welding such as by TIG welding, brazing, resistance welding, electron beam welding, laser beam welding. A three-phase stator winding is thus produced, as in FIG 13 is shown.
The method for producing a stator using the device described above is described with reference to a flow chart which is described in 14 is shown.
The method includes the steps of making a variety of segments 31 . 32 , Twisting the deflection sections 31a . 32a , Pulling out the twisted segments 3 , Holding the stator core 4 with the insulators in the slots 2 , Insert the segments into the slots 2 of the stator core 1 , Turning the edge sections and welding the edge sections 31d . 31e . 32d . 32e , The step of peeling the film may be included before the step of welding or the step of making the segments.
If the deflection sections 31a . 32a the lead holds 16a the deflection sections 31a . 32a partially to limit the circumferential movement thereof. This prevents an increase in the height and in the length of the winding ends of the deflection or winding sections 31a . 32a ,
If the segments 3 into the slots 2 will not be introduced the deflection sections 31a . 32a but the straight sections 31b . 31c . 32b . 32c recorded. That is, the segments 3 are near the edge sections 31d . 31e . 32d . 32e of the segments 3 that in the slots 2 are to be introduced. Therefore, the edge sections 31d . 31e . 32d . 32e be positioned exactly compared to those supported on the deflection sections thereof. As a result, the segments can be prevented 3 be damaged if the segments 3 into the slots 2 be introduced and otherwise with the inner walls of the slots 2 would collide. Even if the number of slots is increased, the segments can 3 be positioned exactly.
The tooth parts 211 and the outside holder 21 keep the segments 3 in the circumferential direction, thereby preventing the segments with the peripheral walls of the slots 2 collide. The outside surface 221a of the inside holder 221 and the outside holding surface 211c of the outside holder 21 keep the segments 3 in the radial direction, which prevents the segments 3 with the radial walls of the slots 2 collide.
The tabs 16a hold the middle of the deflection sections 31a . 32a between the peripheral sides thereof, around the circumferential movement of the segments 3 to restrict or prevent when the segments 3 according to an interference fit in the slots 2 be fitted. The lead 16a limits the segments 3 in shifting circumferentially to prevent the segments 3 with the peripheral walls of the slots 2 collide when the segments 3 into the slots 2 be introduced.
There are a variety of segments 3 processed at the same time according to the following steps: twisting deflection sections; Pull out the twisted segments 3 ; Insert the segments into the slots 2 of the stator core 1 ; Twisting the edge or edge portions; and peeling off the insulating coating. As a result, the number of manufacturing steps and the cost can be reduced.
15 illustrates a step of press fitting the segments into the slots using a stator manufacturing tool according to a second embodiment. The method according to the second embodiment is almost the same as that of the first embodiment, except for a step of press fitting the segments in the slots.
In the second embodiment, the assembling tool has 20 an axial holder 24 of the segments. The axial holder 24 is arranged on the side of the stator core opposite the side of which the edge sections 31d . 31e . 32d . 32e of the segments 3 are inserted from around the edge sections 31d . 31e . 32d . 32e the seg mente 3 hold.
In the step of making an interference fit, the segments 3 pressed in by the presser, while the segments at the edge portions 31d . 31e . 32d . 32e through the axial holder 24 being held.
The segments 3 are press-fitted into the slots 2 fitted while the segments on both edge sections 31d . 31e . 32d . 32e and the deflection sections 31a . 32a are supported or held. The edge sections 31d . 31e . 32d . 32e are held to the segments 3 into the slots 2 insert smoothly in the radial direction. It can therefore damage or destroy the edge portions 31d . 31e . 32d . 32e through the slots 2 is caused to be reduced.
The cross section of the conductor can be circular. If each of the segments has a circular cross-section, the segment holders 111 . 112 . 121 . 122 of the twisting tool 10 circular for the deflection sections.
The holders for moving the multitude of segments 3 can be separated from the guides for the edge sections 31d . 31e . 32d . 32e of the straight sections 31b . 31c . 32b . 32c the multitude of segments 3 in the openings of the slots 2 be trained.
For example, two holders can be provided in the axial direction so that the upper holder can be used as a segment holder and the lower holder can be used as a segment guide instead of the unitary holder 21 according to the first embodiment.
The segments 3 can be arranged in a single circumferential layer instead of in multiple layers. In this arrangement, the holders are 21 . 22 , which are described in the embodiments explained above, in the movement of the plurality of segments and in the insertion of the same in an exact manner into the stator core 1 into it, efficiently.
The present invention relates to a method and an apparatus for manufacturing an alternator for a Vehicle such as a passenger vehicle, a truck or similar. The procedure and device according to the embodiment The invention is in connection with a powerful vehicle alternator useful.
Conductor twisting device for twisting sections of turns ( 31a . 32a ) of U-shaped conductor segments ( 3 . 31 . 32 ) which are in a plurality of circumferentially distributed slots ( 2 ) of a stator core ( 1 ) are inserted, the device comprising the following: a first swiveling or rotating tool ( 11 ), which is on straight sections ( 31b . 32b ) of the U-shaped conductor segments ( 3 . 31 . 32 ) holds a second swivel or turning tool ( 12 ), which is on other straight sections ( 31c . 32c ) of the U-shaped conductor segments ( 3 . 31 . 32 ) holds and relative to the first swivel or turning tool ( 11 ) can be pivoted or rotated, and a circumferential holder ( 16a ), which is a middle section of the winding sections ( 31a . 32a ) of the U-shaped conductor segments ( 3 . 31 . 32 ) in the circumferential direction of the first and the second swiveling or rotating tool in order to prevent the circumferential movement of the winding sections ( 31a . 32a ) restrict.
A conductor twisting device according to claim 1, wherein the peripheral holder ( 16a ) only the middle section of the winding sections ( 31a . 32a ) holds.
Conductor twisting device according to claim 1 or 2, characterized in that it is a segment pressing device ( 16 ) which is in contact with the upper section of the winding sections ( 31a . 32a ) of the conductor segments ( 3 . 31 . 32 ) when the straight sections ( 31b . 31c . 32b . 32c ) of the conductor segments ( 3 . 31 . 32 ) by the first and the second swivel or turning tool ( 11 . 12 ) being held.
Conductor twisting device according to one of Claims 1 to 3, in which the circumferential holder ( 16a ) has a projection that extends from the segment pressing device ( 16 ) extends around the central sections of the winding sections ( 31a . 32a ) to hold on opposite circumferential sides of the same.
Conductor twisting device according to one of Claims 1 to 4, in which the U-shaped conductor segments ( 3 . 31 . 32 ) contain overlapping conductor segments with different radii of curvature, the first swivel or turning tool ( 11 ) and the second swivel or turning tool ( 12 ) straight sections ( 31b . 31c . 32b . 32c ), which extend from opposite sides of the winding sections ( 31a . 32a ) of the overlapping conductor segments ( 3 . 31 . 32 ) with the different radii, and the circumferential holder ( 16a ) the circumferential movement of the overlapping winding sections ( 31a . 32a ) limits.
Head twisting device according to one of the An Proverbs 1 to 5, in the case of retaining holes ( 111 . 112 . 121 . 122 ) in the first swivel or turning tool ( 11 ) and in the second swivel or turning tool ( 12 ) are provided in the axial direction thereof, and the holding holes ( 111 . 112 . 121 . 122 ) the straight sections ( 31b . 31c . 32b . 32c ) of the conductor segments ( 3 . 31 . 32 ) hold.
A conductor twisting device according to claim 6, in which as many holding holes ( 111 . 112 . 121 . 122 ) as a number corresponding to the number of slots ( 2 ) are provided at equal intervals in the circumferential direction.
Conductor twisting device according to one of claims 1 to 7, characterized in that it is a segment impact device ( 17 ) which is located on the side of the first and the second swiveling or rotating tool ( 11 . 12 ) compared to the segment press device ( 16 ) is arranged, the impact device ( 17 ) the conductor segments ( 3 . 31 . 32 ) to the segment press device ( 16 ) bumps after the winding sections ( 31a . 32a ) have been twisted.
Method of twisting a plurality of conductor segments, with the following steps: a fixing step according to the introduction of straight sections ( 31b . 31c . 32b . 32c ) of U-shaped conductor segments ( 3 . 31 . 32 ), which form a stator winding, in retaining holes ( 111 . 112 . 121 . 122 ) a first swivel or turning tool ( 11 ), which pivots or rotates in a circumferential direction, and a second swiveling or rotating tool ( 12 ), which is coaxial with the swivel or rotary tool in the opposite circumferential direction ( 11 ) pivots or rotates, a winding section holding step for holding only a central section of the winding sections ( 31a . 32a ) to the circumferential movement of the first and the second swiveling or rotating tool ( 11 . 12 ) and a twisting step to twist the U-shaped conductor segments ( 3 . 31 . 32 ) by swiveling or rotating the first swivel or turning tool ( 11 ) and the second swivel or turning tool ( 12 ) relative to each other, while the winding sections ( 31a . 32a ) of the U-shaped conductor segments ( 3 . 31 . 32 ) are only held in the middle.
The method of claim 9, wherein the middle portions of the turn portions ( 31a . 32a ) are held on circumferentially opposite sides thereof in the bending position holding step.
The method according to claim 10, further comprising a pressing step according to the pressing of the winding sections ( 31a . 32a ) on the upper area of the same with the help of a segment press device ( 16 ).
The method according to claim 11, wherein the winding section holding step includes a step of holding the middle sections of the winding sections ( 31a . 32a ) by a head start ( 16a ) which extends from the segment press device ( 16 ) extends on opposite circumferential sides of the same.
Method for twisting a plurality of conductor segments according to one of Claims 9 to 12, in which the fixing step comprises a step in accordance with the arrangement of the plurality of U-shaped conductor segments ( 3 . 31 . 32 ) in a circumferential direction.
Method for twisting a plurality of conductor segments according to one of Claims 9 to 13, in which the fixing step comprises a step according to an overlap of winding sections ( 31a . 32a ) the large number of U-shaped conductor segments ( 3 . 31 . 32 ) which comprises different winding sections ( 31a . 32a ) with regard to the radius of curvature, a step according to the introduction of straight sections ( 31b . 31c . 32b . 32c ) of half of the winding sections ( 31a . 32a ) in holding holes ( 111 . 112 ) on the first swivel or turning tool ( 11 ), and another step according to an introduction of the straight sections ( 31b . 32b . 31c . 32c ) of the other half of the winding sections ( 31a . 32a ) in the holding holes ( 121 . 122 ) of the second swivel or turning tool ( 12 ) includes.
Method according to one of Claims 9 to 14, characterized by a step in accordance with the butting of the conductor segments ( 3 . 31 . 32 ) by a push device ( 17 ) on the side of the first and the second swivel or turning tool ( 11 . 12 ) compared to the segment press device ( 16 ) is arranged to the segment press device ( 16 ) after the winding sections ( 31a . 32a ) were twisted.
DE1998616263 1997-10-16 1998-10-14 Method and device for rotating u-four stator winding pops Expired - Lifetime DE69816263T3 (en)
DE69816263D1 DE69816263D1 (en) 2003-08-14
DE69816263T2 true DE69816263T2 (en) 2004-05-13
DE69816263T3 DE69816263T3 (en) 2007-09-13
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2007-07-05 8366 Restricted maintained after opposition proceedings