NO145145B - MULTI-ROEBELSTAV. - Google Patents

Description

The present invention relates to a multi-Koebel rod, which consists of at least two Roebel rods which are twisted separately, preferably two-plane Roebel rods.

Multi-Roebel rods have long been known in Bodefeld/Sequenz: Elektrische Maschinen, Springer Verlag, Wien - New York,

l<y>71, p. 124). They are used in large alternating current machines with wide stator slots. The most common is the double Roebel stick, which consists of two two-plane Roebel sticks, which are twisted separately. The individual poles are electrically separated throughout the entire phase winding. Only at the end of the phase winding are both parallel circuits connected. In the case of windings, where the number of parallel current circuits corresponds to the even number of poles, the position of the individual rods in each of the two coil groups per phase winding is changed from left to right or vice versa in order to avoid large loop currents (SchlingstrSme) which are due to induced voltages as a result of tangential displacement of the position. In the two-layer windings, a crossed connection of the individual rods is used for the bottom and top rod (Grund- und Bohrungsstab); this only at one specific place for each coil group, so that the vector sums of all rod loop voltages reach a minimal value (Sequenz: Herstellung der Wicklungen elektrischer Maschinen, Springer-Verlag, Wien - New York, J.97J, pp. 78-80, Fig. 1). This constructive solution, however, requires extra space in the axial direction and thus possibly even an increase in the bearing distances. Another disadvantage of this construction lies in the fact that different rods with individual involute lengths must be produced.

At the heart of the invention lies the task of providing a multi-Roebel rod, which does not have the disadvantages of the known designs and with simple means compensates for the effect of the radial field.

Said task is achieved according to the invention by a multi-Roebel rod of the initially mentioned type in that the Roebel rods which

is twisted separately, because each coil group is twisted together in one of the coil head hoops.

The advantage of the invention lies particularly in that. by means of this twisting, the effect of the radial field can be compensated in a simple way without having to change the machine's bearing distances. No additional connecting parts are needed and the muiti-Roebel rod's individual rods remain individually manipulable during assembly and disassembly.

It is also appropriate for the multi-Roebel rod to include scattered hole conductors. The hollow part conductors enable intense liquid cooling. In another embodiment, it is advantageous that the partial conductors for the individual Roebel rods, which are twisted separately, are also twisted separately next to the twisted coil head braces. With these features, a radial fat compensation is achieved, also in each €<*>rod, which in the coil head braces where the individual Roebel rods are twisted together is lost in favor of radial field compensation in the multi-Roebel rod.

In the drawing, an embodiment of the object of the invention is shown in a simplified representation.

Fig. 1 shows an embodiment of the invention.

Fig. 2-4 are cross sections II-IV from fig. 1.

Fig. 5 shows an embodiment of a winding with the object of the invention.

In fig. 1 is a coil head bracket part of a double Roebel rod shown schematically. The single two-plane Roebel rod, which is located on the left at the beginning of the coil head hoop part, is designated by 1, the right one is designated by 2. The single conductors, which are located in the upper layer at the beginning of the coil head hoop part, are designated by 1' in the left rod and in right rod with 2'. Of the cross-sections II-IV as shown in fig. 2, it will be clear that the twist, which in this example is 180°, involves a replacement of the individual rods 1 and 2. For reasons of clarity, only the individual conductors for the original left rod 1 are fully drawn in fig. 2-4. The cross-sectional surface of the originally right rod 2 is shown in dashed lines. In fig. 2-4 you can see the change in position of the single conductors 1", which at the beginning of the coil head bracket part (fig. 2) lay in the upper layer of the left rod 1. The single conductors 1' are behind section II together bent so far to the right that they lie on right rod 2. All sub-conductors of the originally left-hand rod 1 will rise within the involute of the coil head bracket to the top layer and then turn over to the right side. At the same time, all (not shown in fig.2-4) sub-conductors of the originally right-hand rod 2 to the bottom layer within the involute and then continue to the left side.

In fig. 5, which shows a winding with the double Roebel rod according to fig. 1, corresponding parts are provided with the same reference number as in fig. 1-4.

The object of the invention is of course not limited to what is shown in the drawing. Thus, the multi-Roebel rod can comprise more than two single rods and some massive conductors can be replaced by hole conductors.

Claims (3)

1. Multi-Roebel rod, which consists of at least two Roebel rods that are twisted separately, preferably two-plane Roebel rods, characterized in that the Roebel rods (1, 2) that are twisted separately for each coil group are twisted together in one of the coil head brackets . 2. Multi-Roebel rod as specified in claim 1, characterized in that it contains scattered hole conductors. 3. Multi-Roebel rod as specified in claim 1, is characterized by the fact that the sub-conductors for the individual Roebel rods (1, 2) which are twisted separately, are also twisted separately on the side of the twisted s <p>ole head braces.