DE3803752A1 - STAND FOR A MOTOR VEHICLE THREE-PHASE GENERATOR AND MANUFACTURING METHOD THEREFOR - Google Patents

Abstract

The stator includes a core 2 having a plurality of slots formed in its inner periphery; a stator winding 7 partially inserted in each of said slots of said stator core; and an electrically insulating material inserted between said stator winding and the surface of said stator core opposing said stator winding, wherein said slots formed in said stator core have a substantially rectangular cross-sectional form and the portions of said stator winding to be inserted into said slots also have a substantially rectangular cross-sectional form, with the other portions 7b having a circular cross-sectional form. The rectangular cross-section of the winding portions is achieved before insertion in the slots by a hydraulic presser plate 15. The winding conductor initially may be of hollow cross-section. <IMAGE>

Description

The invention relates generally to three-phase generators, ins special a stand that is for use in a force Vehicle three-phase generator or the like is suitable, small can be built and works with improved performance; the invention further relates to a method of manufacture of this stand.

For such a stand in a three-phase generator Tor is used for motor vehicles, z. B. after the JP-OS 55-79 660 a solid electrical wire with a circular cross cut into grooves formed in the stand while maintaining its cross-sectional shape inserted, being along circumferentially moderately opposite edges of the end of each tooth a stator core stack approaches are formed around are folded so that partially closed openings are formed for the grooves.  

According to JP-OS 55-94 567 a similar massive Elek trowire with circular cross-section in grooves formed in the stand inserted, and the wire or the winding is in the direction of the groove depth in order to thereby fill the fill factor (ver ratio of the area occupied by the winding to the area taken up by the groove). Close Lich opposite edges of the ends of the teeth of the stator core is extended in the circumferential direction to to form partially closed openings for the grooves.

However, since the mas sive electrical wires or the winding with a circular cross-section inserted in the grooves without changing their cross-sectional shape the fill factor cannot be improved because between successive turns of the windings gaps between them are necessary. It does it difficult to adjust the power level of the alternator improve. For the stand where the massive electric wire with a circular cross section can be pressed of the winding in the slots partially over each other cross, so that it may become impossible to find the right one Comply with the arrangement of the turns of the winding. Consequently can during the pressing of the winding on the Wick Insulated coating applied to the surface of the insulation the so that the windings are short-circuited. The Use of such a method thus leads to a Larger rejects in a mass production process and thus a reduction in productivity.

It is well known that in particular large orbiting electrical machines instead of a round wire a fla Use a wire with a square cross-section. If but such a flat square wire as it is, used in small three-phase generators or the like the following disadvantages. Before inserting in the grooves the winding is usually given a predetermined shape. In a mass production process to produce a  large winding volume within a short time with the help of winding machines is the use of this type of fla Chem square wire is not suitable as this wire is concerned Inferior to the round wire in terms of its processing ability is because of the presence of curvatures or Twists on its winding head sections.

The object of the invention is therefore to provide a Stand that is for use in a motor vehicle shoot Current generator is suitable, and a method for Her position of such a stand, the fill factor of a Winding is significantly improved, thereby reducing the lei power level of the three-phase generator to increase, where fer ner during the assembly of the winding cover in none Way is damaged, and the productivity of ver driving is significantly improved.

The stand according to the invention for a motor vehicle Three-phase generator, with a stator core, in which Several grooves are formed on the inner circumference, with a stand winding into the grooves in the stator core put sections, and an insulating material between inserted the stator winding and the stator core is characterized in that in the stand laminated grooves formed essentially square cross have a sectional shape, and that the inserted into the grooves Stator winding sections also square cross-section have shape while the rest of the stator winding circle has cross-sectional shape.

According to the invention is part of the in the grooves of the stand The inserted winding is shaped so that the in the grooves used winding parts essentially square cross cut shape obtained by applying pressure so that the filling factor of the winding in the slots considerably ver is improved. Since the winding is also made of winding material  there is at least a circular cross-sectional shape various disadvantages can be eliminated, that have previously occurred during winding formation.

Using the drawing, the invention is for example explained in more detail. Show it:

Figure 1 is a cross section of part of a stator for a motor vehicle alternator according to the invention.

Fig. 2 is a view II-II of Fig. 1;

Fig. 3 to 5 representations illustrating the formation of a stator winding for the stator according to the invention for installation in a motor vehicle three-phase generator; while FIG. 3 shows the winding state of the winding material according to the invention, Fig. 4 is a Perspektivan view showing the operation of pressing the Wick development material of Fig. 3 with a press mold, and Fig. 5 shows in perspective a stator winding according to the Invention is put forth;

Fig. 6 is a perspective view of a stator core package according to the invention for a motor vehicle three-phase generator, showing a state in which extensions that serve as magnetic flux collectors are not yet ge forms;

FIGS. 7A and 7B are schematic diagrams showing a process for producing serving as Magnetflußsammler portions of the stator according to the invention for an automotive alternator, in which Fig. 7A shows the state in which a stator coil is inserted into the stator slots, and Fig. 7B shows the state in which the end face of each tooth portion of the stator core is molded under pressure;

FIGS. 8A and 8B are cross-sectional views of another example of the stator winding of the stator according to the OF INVENTION dung for a motor vehicle Drehstromgenera gate, wherein FIG. 8A shows a cross section through a hollow wire and FIG. 8B shows the hollow wire, the under pressure in wesentli Chen quadrilateral cross-section is deformed;

9 shows a cross section through an automotive alternator in which the stator is installed according to the invention. and

Fig. 10 is a graph showing a comparison between the power curve of a motor vehicle alternator containing a stator according to the invention and the power curve of a conventional motor vehicle alternator.

Fig. 1 shows in cross section a part of the armature of a motor vehicle alternator, ie a stand 1. The stator 1 has a stator core 2 made of layered steel sheets, each of which has a predetermined punching shape. The stator core 2 comprises a cylindrical part 3 and a plurality of teeth 4 , which each project in the radial direction from the cylindrical part 3 inwards, and between adjacent teeth 4 , a groove 5 is in each case be limited. The groove 5 has a square cross section. In the vorlie embodiment of the stator 1 suitable for a motor vehicle alternator, twelve grooves are formed in the cylindrical part 3 of the stator core 2 on the inner circumferential side thereof. Fig. 1 shows an example of only three of these grooves. Two extensions 6 , which are circumferentially elongated in opposite directions, are formed on the circumferentially opposite edges of the inner end of each tooth 4 . Each extension 6 has the function of collecting magnetic flux and limiting the partially closed opening of the groove 5 to prevent a winding from protruding therefrom, as will be explained.

In the present embodiment, a stator winding 7 , each with six win applications, is used in each slot 5 of the stator 1 . Of course, this stator winding is wound so that a three-phase output is obtained as in known motor vehicle alternators. Between the stator core 2 and the stator winding 7 is a thermally very resistant insulating paper 8 , for. B. Nomex (Wz) arranged. This provides a cohesive electrical insulation between the stator core 2 and the stator winding 7 .

As clearly shown in FIG. 2, the stator winding 7 accommodated in the groove 5 of the stator core 2 comprises a section 7 a and end windings 7 b . The section 7 a is inserted into the groove 5 and has a flat or square cross-section. The remaining sections or end windings 7 b have a circular cross-sectional shape. Since, as can be seen, each slot 5 with a substantially square cross section receives a winding which also has a square cross section, the filling factor of the winding in the stator slot 5 is improved.

A method for manufacturing the stator winding 7 explained above will be described below.

Referring to FIG. 3, a solid electric wire material 17 is several times with circular cross-section, z. B. six times, wound in wesent union square shape, whereby a winding with a predetermined shape is prepared. In the example described, the winding material 17 is wound into a substantially quadrangular shape, and winding heads 17 b are made arcuate. Therefore, if the winding is inserted into the groove 5 of the stator core 2 , the winding head 17 b can be processed in a simple manner. Furthermore, since electric wire with a circular cross section is used, there is no deterioration in workability due to twisting of the electric wire, in contrast to the case in which the winding is wound from so-called square wire. It is therefore not necessary to watch out for twisted electrical wires. It can thus be seen that the winding material described is suitable for use in mass production because of its superior processability.

After the stator winding material 17 is wound in the manner described to a predetermined shape, its portion 17 a , which is to be inserted into the groove 5 , is brought into a flat shape by a compression molding device 9 . The press mold device 9 comprises a base 10 , a stop 11 arranged centrally in the longitudinal direction of the base 10 , two at the opposite ends in the longitudinal direction of the base 10 to ordered blocks 12 , two slides 13 which can be pushed in the longitudinal direction over the base 10 , springs 14 , which are each fixed at one end to a block 12 and at the other end to a slide 13 , and a pressure member 15 , which can be moved by hydraulic pressure or the like in the vertical direction. The corresponding to FIG. 3 shaped winding is material disposed between the stop 11 and the sliders 13, and its sections 17 a, which is an enforce in the grooves, that is, not the winding heads 17 b, by the force of the springs 14 in this Situation noted. Then the inserted sections 17 a are pressurized by the pressure organ 15 in the direction of the arrow. By this pressing, the winding material 17 is formed into a stator winding 7 as shown in FIG. 5, wherein the sections 7 a to be inserted into the groove 5 have a substantially rectangular shape in cross section. After the winding material has been wound in the embodiment described above and the winding thus obtained has been arranged such that its windings lie one above the other, predetermined parts of the windings lying one above the other are pressurized. However, after only the predetermined parts of the winding material have been pressurized, the winding material obtained can be wound into the desired shape.

The stator winding 7 manufactured in the above manner is firmly inserted into each of the grooves 5 formed between the adjacent teeth 4 of the stator core 2 of FIG. 6 with an insulating paper interposed. As shown in FIG. 6, an essentially elliptical through hole 16 is formed in the axial direction through each tooth 4 of the stator core 2 . As will be described, who the already mentioned approaches 6 , which serve as a magnetic flux collector, formed by pressing the end face of each tooth 4 . This makes it possible to prevent the inserted windings from falling out of the slots 5 . From the above description it can be seen that after insertion of the winding 7 into the groove 5 of the approach 6 serving as a magnetic flux collector 6 is formed on the end face of the tooth 4 of the stator core 2 . Thus, a winding 7 with a substantially square shape without Wei teres can be used in each slot 5 . It should be noted that the assembly performance is significantly improved, especially in a mass production process.

The following is a description of a method for forming the approaches of the stator core 2 that serve as magnetic flux collectors.

Referring to FIG. 7A 5 six turns of winding of the STAs are inserted 7 in each groove, wherein the surface of the insulating groove 5, 8 is arranged between the coil 7 and in each case.

Then, according to FIG. 7B, the end face of the tooth 4 of the stator sheet stack 2 is pressurized in the direction of arrow F by a suitable pressure device (for example a press or a roller). As the solid lines in FIG. 7B show, the ends of the teeth 4 are pressed together in the axial direction by setting through openings 16 , and at the same time the sections of the stator core 2 , which adjoin the circumferentially opposite sides of the through hole 16 , become parallel to the circumference of the stator core 2 pressed outwards. This makes it possible to shape the magnetic flux collector 6 so that each has an ideal shape approximating an arc.

In the embodiment explained above, a solid electrical wire with a circular cross section is used for example to form the stator winding. In the present invention, however, a hollow wire 27 as shown in FIG. 8A can also be used instead of the round wire. As shown, this originally has a circular or ring cross section. When pressing the hollow wire 27 , the water assumes an elongated shape with rounded ends according to FIG. 8B. 4, the hollow wire 27 is used, it can be seen that the required pressing force can be reduced compared to the round wire, and it is possible, in a simple and positive manner, in the pressing process, which was explained in conjunction with FIG to deform the round wire into a square cross-section. Of course, the sections of the hollow wire 27 to be inserted into the grooves are deformed into a flat shape. Furthermore, the pressing pressure required for processing the hollow wire can be reduced compared to the processing of a solid electrical wire. Thus, the risk of damage to an insulating layer applied to the winding during the pressing process is less, and the reject rate can be reduced to an extremely low value.

Fig. 9 shows in cross section a motor vehicle three-phase generator with the stator 1 described above. Fig. 10 shows a comparison between the power curve of a typical known three-phase generator and that with the stator according to the invention. From Fig. 10 it follows that it is possible with the stand according to the invention to improve the fill factor to a value of approximately 80%. As a result, it is possible, as shown in FIG. 10, to increase the power level over the entire speed range of the three-phase generator compared to the known three-phase generator of the same size (the power curve of which is indicated by broken lines). In particular, it has been shown that the power level could be increased by about 25% in accordance with the full line at a nominal speed of 5000 rpm.

From the above description it can be seen that by the invention a stand with a large fill factor for Use in a motor vehicle three-phase generator specified becomes; this makes it possible to shoot a motor vehicle to create electricity generator that can be built small and whose output power is high.

Claims (8)

1. Stand for a motor vehicle alternator, with
a stator core ( 2 ), in the inner circumference of which a plurality of grooves ( 5 ) are formed;
a stator winding ( 7 ) with sections inserted into the slots of the stator core; and
an insulating material ( 8 ) inserted between the stator winding and the stator core;
characterized in that the slots ( 5 ) formed in the stator core ( 2 ) have a substantially quadrangular cross-sectional shape, and in that the stator winding sections inserted into the slots also have a quadrangular cross-sectional shape, while the rest of the stator winding has a circular cross-sectional shape. 2. Stand according to claim 1, characterized, that the rest of the stator winding has a hollow cross-sectional shape.   3. Method of making a stand for one Motor vehicle three-phase generator, the stand being a Stator core with a plurality of inside circumferentially formed slots, a stator winding, which in each sections of the slots of the stator core and one between the stator winding and the stalk the laminated core has inserted insulating material, marked by Pressing the sections of the to be inserted into the grooves Stator winding from their circular cross-sectional shape to one in essential square cross-sectional shape. 4. The method according to claim 3, characterized, that the stator winding from a winding material with a hollow cross-sectional shape is produced. 5. A method of manufacturing a stator for an automotive alternator, the stator comprising a stator core having a plurality of grooves formed in its inner circumference, a stator winding having portions inserted into each of the grooves of the stator core, and one between the stator winding and the Stän derblechpaket has inserted insulating material, characterized by
Winding a winding material having a circular cross-sectional shape into a predetermined winding shape; and
then press molding the sections of the stator winding to be inserted into the slots from their circular cross-sectional shape to a substantially quadrangular cross-sectional shape. 6. The method according to claim 5, characterized, that the stator winding from a winding material with a hollow cross-sectional shape is produced.   7. A method of manufacturing a stator for an automotive alternator, the stator comprising a stator core having a plurality of grooves formed in its inner circumference, a stator winding having portions inserted into each of the grooves of the stator core, and one between the stator winding and the Stän derblechpaket has inserted insulating material, characterized by
Press-forming the sections of the stator winding to be inserted into the slots from their circular cross-sectional shape to a substantially quadrangular cross-sectional shape; and
then winding this winding material to vorbe certain winding shape to form the stator winding. 8. The method according to claim 7, characterized, that the stator winding from a winding material with a hollow cross-sectional shape is produced.