CS170589A3 - Double wedge - Google Patents

Abstract

The double slanting wedge consists of two identical wedge halves (1, 2) which are divided into partial wedges which are mutually identical and are designed as one piece with one another. Each wedge half (1, 2) consists of a stack of partial metal sheets (5) which are layered one on top of the other and are held together by means of a type of rivet connection (7, 8). Wedges of this type are suitable in particular for the wedging of the poles (9) on the rotor ring (11) and of the rotor ring (11) on the wheel spider (13) of electrical machines, can be produced economically and can be fitted and removed again simply. <IMAGE>

Description

The invention relates to a double wedge, in particular to a pole. and a rotor ring of electrical machines, which consists of two equal halves which are slidable along their wedge faces in the longitudinal direction of the wedge and, in relative motion, vary the width of the wedge in the transverse direction.

Dual wedges of this kind are used, in particular, to clamp poles on the rotor ring and rotor ring on a synchronous rotor rotor, as described, for example, by Wiedemann / Kellerberger "Konstruktion elektrischer Maschinen", 1967, p. 37Ο, Fig. 367b. They consist of two halves whose axial length, typically up to 2.5 m, corresponds to the axial length of the pole. The wedge angle is very small compared to conventional wedges. The manufacture of a wedge of such length is relatively complicated, or the assembly thereof is simple, but the wedging of the wedge is practically impossible without damaging the wedge and the surface on which the wedge abuts. The purpose of the invention is to provide a double wedge so that it is economically manageable and allows easy assembly and disassembly.

The essence of the invention is that the wedge surfaces of the wedge-shaped wedge are divided into a plurality of mutually identical wedge-shaped surfaces, which are at least in sections joined to one another, the bevel of each wedge surface corresponding to the bevel of the entire wedge.

Such a wedge can be easily manufactured, especially when assembling individual stamped sheets assembled into a bundle.

As for fitting such a wedge, it is as simple as a conventional double wedge. When dismantling, the double-wedge can be driven out on a substantially shorter path.

The invention will be explained with reference to the exemplary embodiment shown in FIG. in the drawings, where the figure shows a double wedge in the basic position, FIG. 3 shows the wedge of the wedge of FIG. 1, FIG. 4 shows a section of a sheet of sheets at an enlarged scale, and FIG. a simplified cross-section of the hydro-generator rotor ring.

The double wedge of FIG. 1 and z consists of two halves 6. Each half,, má has a plurality of wedge-shaped surfaces 2, ds which abut each other in pairs. In the example shown, each wedge half 5 has five wedge surfaces 1 each of these "wedges" has an angle 6 6 which is five times the angle of a conventional wedge wedge. With a number of "n" partial wedges, the wedge angle is n-fold greater. Length of one wedge surface 2. ' and d. and the angle [omega] of the wedge is selected such that, when the two halves 11, 5 are displaced by half the length l of the wedge, the wedge is the maximum width b. In principle, the wedge halves 11 can be made of solid material. However, it is more economical to assemble the two halves 1, 4 of a large number of individual sheets 6 stacked together and rolled in layers, as shown in Figure 3. . At the same time, through-holes 6 can be produced at the same time, which lie in a bundle of sheets in a single line and thus extend through the entire bundle.

Generally, the effective width b of the double wedge wedge 1 is given by the formula b - bQ + 1. tg &amp; Ó where bQ is the wedge opening width and the wedge angle.

For example, bundles of sheets are riveted together.

However, the joining of the individual sub-sheets 4 can be simplified when, according to FIG. 4, a depression 2 is formed on one side of each sub-sheet 2 and a projection 8 &apos; In this case, the inner diameter d1 is slightly smaller than the outer diameter d1 of the projection 8. The connection of the recess 2 and the projection 8 can take place in a single operation. The depressions 2 and the protrusions 8 can also be formed in a single operation, preferably in the case of stamping sheets 2 with an outer diameter punch d, and punching the depressions with an inner diameter d. When the plates are pressed, the projections 2 are pressed into the recesses 2 and connect a reliable bundle.

FIG. 5 is a simplified illustration of the preferred twin wedges according to the invention. In the upper half of FIG. 5, a pole 2 with a dovetail hinge 10 is disposed in the axial groove in the ring 11 of the pump rotor. The intermediate wall of the groove and the hinge 10 of the pole 2 is a double wedge consisting of two halves 2. The axes 2 and k * 11 of the rotor are keyed to each other by axially displacing the two wedge halves. In the lower part of Fig. 5, the rotor ring 11 is fixed by means of axial connecting strips 12 of rectangular cross section on the outer periphery of the rotor star 13. The rectangular connecting strip 13 has a rectangular axial recess into which a double-wedge consisting of halves 1,2 is inserted. In this case, the wedge connection is tangential.

Claims (4)

PATENT CLAIMS 1. A double wedge, in particular for securing the poles and the ring of the rotor of electrical machines, consisting of two equal / half halves which are displaceable along their wedge faces in the longitudinal direction of the wedges and, when relative to each other, the effective wedge width is variable in the transverse direction; the wedge surfaces of the wedge are divided in a large number of mutually identical wedge surfaces, which are each; half. (1, 2) of the wedge, at least in sections, in a single piece, wherein the effective width b of the double wedge of the displacement of length l is given by the formula b b b + 1. tgd, where bQ is the wedge opening width and cC the wedge angle. 2. Double wedge according to claim 1, characterized in that the wedge halves (i, 2) consist of interconnected individual metal sheets (5). 3. A double wedge according to claim 2, characterized in that on one side the recesses (7) are provided on the one side and the projections (8) on the opposite side adapted to the recesses (7). 4. A double wedge according to claim 1, characterized in that the individual sub-sheets (5) are smaller than the total length and the sub-sheets (5) are mutually offset in the stack. , 1