DE10103824A1 - Stand connector of an electrical machine - Google Patents

Abstract

The invention relates to an electrical machine with a stator winding (11) and a rotor winding (17). The rotor winding (17) is received on a rotor shaft (14) mounted in bearings (15, 16). The windings (11 and 17) are enclosed by end shields (18, 19, 20). Stator connections (6.1 to 6.6) of the stator winding (11) are connected to an internal connection part (1) and are guided to the outside on this.

Description

Technical field

The connector for the stator winding of an electric induction machine, such as Example of a generator for energy generation in vehicles, takes on many different tasks gifts. The connecting part is used to connect the stator winding in a star or in Triangle and as an assembly aid for guiding the connections through the housing. At the The stator connections of the stator winding are connected to the electronic part Component of a rectifier or a pulse inverter connected. At Wasserge cooled generators, the connector can also be used as a seal take to allow the stator winding head to be potted.

State of the art

In electrical machines for energy generation previously used in motor vehicles rectifiers or pulse inverters are usually on the outside of the housing of the elek trical machine attached. Therefore, the stator connections are through the housing of these electrical machines led outside and with the outside of the housing electronic components, with rectifier bridges the diodes or with pulse changes rectify the transistors or the blocking diodes connected. So far the interconnection the stator winding is also made outside the housing. Taking into account the fact that the star / delta connection between rectifiers or pulse change rectifiers and the stator connections of the stator winding must be provided thereby an increased space requirement outside the housing of the electrical machine. Who the six-phase stator windings, the space requirement increases accordingly, since 12 Stand connections are routed through the housing and outside of the housing Star / delta connection must be connected.

In the case of three-phase stator windings, a lead frame with screw connections is also used led out through a bearing plate. With six-phase stator windings, like them  For example, if high-performance generators are required, the use of Punched grids and screw connections due to the increasing space requirements.

Presentation of the invention

With the provision of a connector for connecting the stator connections and whose guidance from the housing of the electrical machine is an exact guidance of the Stand wires created. Before inserting the stand into the stand housing (for Example a bearing plate) the connector is connected to the stator connectors, see above that there is an easier assembly. As a rule, the stand is converted into this shrinking stator housing (end shield) shrunk.

For example, in high-performance generators with six-phase windings individual winding packages within the housing in star or delta connection switches, is the connection part for the defined guidance of the stator connections of the winding extremely helpful. The stator connections on the connecting part are easier to the outside lead, since fewer connections are to be provided, which are freely posio on a small diameter can be renated. There may be holes in the circumference of the stator housing (bearing shield) are omitted in order to lead the stator wires to the outside. Holes in the Bearing shield surrounding the stator winding make water-cooled electrical rotation field machines is a weak point, which with the proposed solution according to the invention solution can be avoided.

Can the stator windings of three-phase electric machines already be used? closing part in the housing to form a star or delta connection is outside the housing of the electrical induction machines more space available, so that the electric induction machine takes up less space. This is when using the elek tric induction machine in the engine compartment of motor vehicles of importance because of there available space due to the increasing number of attachments the internal combustion engine is steadily decreasing and the size of a combustion engine increases with an increasing number of cylinders.

With the use of an internal connector, flexible positioning of the Stand connections made possible from the housing. With water-cooled generators the connecting part at the same time as a sealing element for the potting process of the stand deploy. In order to ensure optimal conductor routing combined with maximum sealing effect the stator connections can be led out of the stator housing  that they are in a suitable position with respect to the rectifier or the pulse inverter escape.

If a connector is used to guide the stator wires out of the stator housing, can connect the stator wires by ultrasonic welding can be connected without stripping the stator wires. In the The manufacture of three-phase electrical machines with six-phase windings provides that Stripping the stator wires represents an avoidable effort. With the fiction According to the proposed use of an internal connection part, the effort the stripping of the stator connections of the winding wires of the winding packages Avoid stator winding.

drawing

The invention is explained in more detail below with the aid of the drawing. It shows:

Fig. 1 a connecting section with the welded stator terminals,

Fig. 2 is a reproduced in an enlarged scale the welding point on the connecting part,

Fig. 3 shows the stand of an electric induction machine with built-in connector and

Fig. 4 shows a longitudinal section through an electric induction machine.

variants

Fig. 1 shows a connecting part with welded stator connecting wires.

An annularly configured connection part 1 comprises an annularly extending front surface 3 and a circumferential surface 2 running perpendicularly thereto. In order to start surface 2 and in the front surface 3 are spaced apart by webs, individual openings 4 are added. In the area of the openings 4 , stator connections 6.1 , 6.2 , 6.3 , 6.4 , 6.5 and 6.6 are openly accessible from the outside. In the illustration of FIG. 1, a ring-shaped connecting part 1 is provided for an electrical induction machine, for example a high-power generator with six-phase stator winding. Instead of the six stator connections 6.1 to 6.6 shown here, which are assigned a corresponding number of openings 4 on the connecting part, a number of openings 4 corresponding to a three-phase winding of the stator can also be provided on the connecting part 1 . Electronic components such as diodes of rectifier bridges (not shown here) and transistors or blocking diodes of pulse inverters can be connected to the stator connections 6.1 , 6.2 , 6.3 , 6.4 , 6.5 and 6.6 . With the electronic components counted up, the electrical induction machine is adapted and regulated with regard to its power output to the vehicle electrical system to be supplied in each case.

Between the individual openings 4 provided in circumferential surface 2 and front surface 3 , web-shaped bridges are formed, on each of which, in the radial direction pointing outward, wing-shaped anti-rotation devices 5 are formed. By means of the wing-shaped anti-twist devices 5 , the connection part designed according to FIG. 1 can be fitted into correspondingly corresponding recesses in the stator iron of an electric induction machine and received in a manner preventing twisting.

From the illustration in FIG. 2, a connection point generated by means of a thermal joining process emerges on an enlarged scale at the connecting part.

The illustration of FIG. 2 is a section of the annular connection part configured according to FIG. Be found. 1 In the area of an opening 4 , delimited by two bridges with wing-shaped anti-rotation devices 5 material bridges of the connection part 1 , a freely accessible section of a stator connection 6.3 is given again. In the area of the breakthrough 4 , the portion of the stator connection 6.3 that extends freely accessible through the breakthrough 4 is enclosed by a hook-shaped stator wire bundle 8, for example bent over 90 °. An electrically conductive connection can be produced between the stator wire bundle 8 bent over at its upper edge and the exposed area of the stator connection 6.3 by means of a thermal joining process. The electrically conductive connection 7 , for example a welding point, can be produced by means of ultrasound welding or by means of resistance welding. Stripping the stator wire bundle 8 , which is only partially shown here, is no longer necessary when using the connection part 1 configured according to the invention. This means that time-consuming preparatory work during assembly, ie pressing the stator winding into the end shields surrounding it, can be dispensed with. In the area of the opening 4 , the contact between the bent end of the stator wire bundle 8 and the open section exposed by the opening is ensured from the stator connection 6.3 . In the example according to FIG. 2, the stator wire bundle 8 consists of four individual winding wires.

From Fig. 2 it also appears that the opening 4 , within which the welding point 7 is positioned, is limited by two material webs of the connecting part 1 , which are first and third, on the front surface 3 and the peripheral surface 2 . At the breakthrough 4 be bridges on the connector part 1 wing-shaped configured Verdrehsi securing tongues 5 are formed. These take over the task of receiving the ring-shaped connection part 1 according to the invention on the stator iron 9 in corresponding recesses 12 and securing it against rotation. This defines well-defined points of departure for the ends of the stator connections 6.1 , 6.2 , 6.3 , 6.4 , 6.5 and 6.6 , of which only the stator connection 6.3 is shown here for reasons of clarity.

From the view in Fig. 3 of the stator is an electrical rotating field machine with built-in connecting part forth in greater detail.

At the top of a stator winding 11 , ie the winding head, an annularly confi gured connecting part 1 is provided. The connecting part 1 lies with its material bridges delimiting the openings 4 and the anti-rotation tongues S formed thereon in correspondingly configured recesses 12 on the upper side of the stator winding 11 on the stator iron 9 . When connecting part 1, as shown in FIG. 3 is a connector, which is equipped on an electric rotary-field machine with a six-phase stator winding 11.

With position number 7, the individual joints between the exposed stator terminals 6.1, 6.2, 6.3, 6.4, 6.5 and 6.6 refers to, within the winding packages, the individual stator winding 9 with the corresponding rack connectors 6.1 to 6.6 are electrically conductively connected. From the choice of the arrangement of the openings 4 on the circumference of the essentially ring-shaped connection part 1 , the position of the upwardly bent stator connections 6.1 , 6.2 , 6.3 , 6.4 , 6.5 and 6.6 can be seen . If a connection part 1 is used on an electrical induction machine whose stator winding 11 is only equipped with three winding packages, only three stator connection wires 6.1 , 6.2 or 6.3 are located on the connection part 1 in an optimized position on the circumference of the connection part 1 depending on the installation space. The electronic components of rectifier bridges or pulse inverters can be connected to the stator connections 6.1 to 6.6 , which are required to control or regulate the electrical induction machine in adaptation to the voltage prevailing in the vehicle electrical system.

The stator winding designated by reference numeral 11 , viewed in the axial direction, is surrounded by the stator iron 9 , which in turn is enclosed by a bearing plate, not shown in FIG. 3, which functions as the stator housing of the electrical rotating field machine.

Fig. 4 shows a longitudinal section through an electrical rotating field machine such as a generator for use in a motor vehicle.

FIG. 4 shows an electrical induction machine in which a stator winding 11 and a rotor winding 17 are received. The rotor winding 17 is seated on a rotor shaft 14 which is received in a B-bearing plate 20 by means of a roller bearing 15 and in the A-bearing plate 18 by means of a roller bearing 16 . Between an outer Kä fig, which surrounds the rotor winding 17 and the inside of the stator winding 11 , a minimal air gap is formed, which enables rotation of the rotor shaft 14 in the cavity 23 relative to the inside of the individual stator winding packages of the stator winding 11 .

From Fig. 4 it can also be seen that the inventive ring-shaped and internally configured connector 1 with its peripheral surface 2 is pushed onto the stand iron 9 ben. Between the inside of the stator iron 9 and the peripheral surface 2 of the ring-shaped inner connector 1 , an axial guide 21 is ausgebil det. The axial guide 21 on the inside of the stator iron 11 is supported by the flügelför shaped extensions 5 , which act as radial guides 22 , which engage in corresponding recesses 12 from the stator winding of the stator iron 9 , so that centering of the connecting part 1 as well as one Axial securing of the connecting part 1 on the stator iron 9 or the ring-shaped connecting part 1 surrounding B-end shield 19 , ie the inner part of the B-end shield 19 is ensured. The inner connecting part 1 of the apertures 4 and arranged there electrical joints 7 perform in the field of individual stator wire bundle 8 to which an individual, not shown here winding packages 10 of the stator winding. 11 For the sake of clarity, only one stand of wire bundle 8 is shown in the illustration according to FIG. 4. The stator wire bundles 8 leading to the five winding packages 10 of the stator winding 11 not lying in the plane of the drawing are not shown here, but are obtained in an analogous manner.

The stator iron 9 accommodating the stator winding 11 is pressed into a B-type end shield 19 , ie into the inner part thereof. The connecting part 1 , on which the not reproduced here, but shown according to FIGS . 1 to 4 stator connections 6.1 to 6.6 are seen before, can be switched internally in the B-end shield 19 in star or delta connection before it is in the B Bearing plate 19 is shed. The internal connection part 1 is attached to the stand 11 or 9 on the connection side. There now follows a welding of the stator terminals 6.1 to 6.6 to the inner connecting part 1 and the exposed within the apertures 4 portions of the individual stator terminals 6.1 to 6.6 and the stator wire bundles 8 (see the view in Fig. 2). Then the stator iron 9 is pressed with the internal connection part 1 attached to it into the bearing plate 19 and then cast in this. The B-bearing plate 19 is supported in the B-bearing plate 20 by means of the roller bearing 15 , which is received on a slip ring assembly 24 on the rotor shaft 14 . On the side opposite the roller bearing 15 , the two-part B bearing plate 19 or 20 is closed by means of an A bearing plate 18 , in which the further roller bearing 16 , which rotatably supports the rotor shaft 14, is accommodated.

On the slip ring assembly 24 , which is taken up on a pin of the rotor shaft 14 , there is a disk-shaped body 25 on which connections 26 for the rotor winding 17 are received. On a collar 27 formed on the bearing sleeve 24, there is a supporting, disk-shaped body which delimits the rotor winding 17 .

With the reference numerals 6.2 and 6.5 two stator connections are shown in the illustration according to FIG. 4 as an example. These are guided at openings provided in the B-end shield 20 from the interior of the electrical induction machine. Of the six stator connections 6.1 to 6.6 provided for a six-phase stator winding, the stator connections 6.2 and 6.5 are selected here as examples. On these who the electronic components listed above, a rectifier bridge or a pulse inverter, which are not shown in detail here, electrically attached tend.

From Fig. 4 also shows that by fitting the inner connector 1 in the region of its axial guide 21 or its radial guide 22, a sealing of the interior 23 of the electric induction machine on the side of the B-end shield can be brought about. Thus, the proposed solution according to the invention is also suitable for use on water-cooled electrical induction machines. The electrically conductive connections 7 shown in FIGS. 2 and 3 are preferably produced as welded connections by means of the ultrasonic welding method or resistance welding. The use of this method is made possible, on the one hand, by the perforations 4 formed on the connecting part 1 independently of one another on its peripheral surface and the portions of the stator connections 6.1 to 6.6 exposed there. If the above-mentioned thermal joining methods are used, stripping of the individual stator wire bundles 8 to the individual winding packages 10 of the stator winding 11 can be avoided in particular, be it a 6-phase winding or a 3-phase winding.

LIST OF REFERENCE NUMBERS

1

connector

2

peripheral surface

3

front surface

4

breakthrough

5

twist

6.1

first stand connection

6.2

second stand connection

6.3

third stand connection

6.4

fourth stand connection

6.5

fifth stand connection

6.6

sixth stator connection

7

electrical connection point

8th

Stand wire bundle

9

stator

10

winding package

11

stator winding

12

recess

13

runner

14

rotor shaft

15

roller bearing

16

roller bearing

17

rotor winding

18

A-end shield

19

B-bearing shield inner part

20

B-end shield

21

axial guidance

22

radial guide

23

cavity

24

Slip ring assembly

25

contact disc

26

Connections rotor winding

27

Federation

Claims (9)

1. Electrical machine with a stator winding ( 11 ) and a rotor winding ( 17 ) which is received on a rotor shaft ( 14 ) mounted in bearings ( 15 , 16 ) and encloses the stator winding ( 11 ) by end shields ( 18 , 19 , 20 ) is characterized in that stator connections ( 6.1 to 6.6 ) of the stator winding ( 11 ) are connected to an internal connecting part ( 1 ) and are guided to the outside thereof. 2. Electrical machine according to claim 1, characterized in that the interior lying connecting part ( 1 ) is received on one of the end shields ( 18 , 19 , 20 ). 3. Electrical machine according to claim 2, characterized in that the inner lying connecting part ( 1 ) is pushed onto the stator winding ( 11 ) and centered on a La gerschild inner part ( 19 ). 4. Electrical machine according to claim 1, characterized in that the closing part ( 1 ) comprises a peripheral surface ( 2 ) and a front surface ( 3 ). 5. Electrical machine according to claim 4, characterized in that in the order to start surface ( 2 ) and the front surface ( 3 ) openings ( 4 ) are formed. 6. Electrical machine according to claim 5, characterized in that the openings ( 4 ) release sections of the stator connections ( 6.1 to 6.6 ). 7. Electrical machine according to claim 5, characterized in that the connec tion points ( 7 ) of the stator connections ( 6.1 to 6.6 ) are in the region of the openings ( 4 ). 8. Electrical machine according to claim 5, characterized in that wing-like tongues (S) are formed on the connecting part ( 1 ) on webs lying between the openings ( 4 ), which rest axially on the stator winding ( 11 ). 9. A method for connecting stator connections ( 6.1 to 6.6 ) of a stator winding ( 11 ) of an electrical machine with a connecting part ( 1 ), characterized in that the electrical connection points ( 7 ) of the stator connections ( 6.1 to 6.6 ) with the stator winding ( 11 ) by ultrasonic or resistance welding without stripping the stator wire bundles ( 8 ) before the stator winding ( 11 ) is pressed into and cast in the end shield ( 18 , 19 , 20 ).