DE9003390U1 - Electric synchronous machine with a salient pole rotor - Google Patents

Description

GR 9064037 Siemens Aktiengesellschaft

Electric synchronous machine with a salient pole rotor 5

The invention relates to an electrical synchronous machine with a salient pole rotor, the salient poles of which are designed as long poles and each have a solid pole shaft and a separate pole shoe, which is fastened to the yoke ring with at least two studs arranged one behind the other in the longitudinal direction, each stud being screwed into a threaded hole in the pole shaft and its nut resting on the radially inner surface of the yoke ring.

Such a fastening of the long poles of a salient pole rotor is known from Moeller Werr "Guide to Electrical Engineering", Volume 3, third edition 1955 "Design and strength calculations of electrical machines", pages 47/48 (especially Figure 48.2). There, a stud screw is used to fasten the pole, which is screwed into a threaded hole in the solid pole shaft, designed as a blind hole. This screw must absorb the centrifugal force of the pole and the pole coil, which determines its core cross-section. Since electrical machines have ever higher speeds and are subject to correspondingly higher centrifugal force stresses, correspondingly large screw diameters result, which are difficult to handle and store.

For fastening round poles of electrical synchronous machines, it is also known to use centrally arranged head expansion screws where the screw head is located in a hole in the solid pole shaft on the side facing the pole shoe (see DE-PS-26 05 539).

The invention is based on the task of improving the fastening of the long poles of a salient pole rotor so that without

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D 3 Nim / 19.03.1990 ·■

^2GR 90G4037

Making production and assembly more difficult as high centrifugal forces can be absorbed.

To solve this problem, in an electrical synchronous machine of the type described at the beginning, according to the invention, a shaft expansion screw is used as a stud screw, which, screwed into a through-threaded hole in the pole shaft, rests with the radially outer end face on the radially inner surface of the pole shoe, and the shaft expansion screw has a polygonal projection on the other radially inner end face, which is smaller than the thread diameter.

When using such a shaft expansion screw, known per se, for fastening long poles according to the invention, the threaded hole in the solid pole shaft is designed as a through hole and is therefore easy to manufacture. By placing one end face of the shaft expansion screw on the radially inner surface of the pole shaft, a good, almost gap-free transition of the magnetic field is achieved. Furthermore, the polygonal attachment provided on the other, radially inner end face enables the shaft expansion screw to be easily screwed in or out of the through threaded hole of the pole shaft from the side, so that even when the salient pole rotor is installed, the long pole can be completely detached from the yoke ring and this can therefore be removed in the axial direction.

The part of the shaft expansion screw located in the area of the yoke ring between the thread areas is available as the expansion length for the shaft expansion screw. It is advantageous to choose this expansion length smaller than the height of the yoke ring, so that the end areas of the thread that protrude into the through hole of the yoke ring on both sides can be used to center the shaft expansion screw. This prevents the long pole from jamming during assembly.

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3 GR 90G4037 A particularly advantageous embodiment of the invention with regard to accessibility during assembly and disassembly and the transmission of forces to the rotor shaft is obtained when each long pole is attached to the yoke ring by shaft expansion screws arranged in pairs in the longitudinal direction symmetrically to the central connection between the yoke ring and the hub body of the rotor. In addition, recesses can be provided in the hub body which, in terms of position, number and dimensions, correspond to the shaft expansion screws and are located opposite their radially inner end face. In this way, the height of the free space between the yoke ring and the hub body required for the removal of the long poles due to the height of the shaft expansion screw is reduced without the cross-section of the hub body available for torque transmission being restricted too much.

In the following, the invention is explained in more detail using the embodiment shown schematically in the drawing, to which the invention is not limited, however. The figure in the drawing shows a longitudinal section through a pole of the salient pole rotor of an electrical synchronous machine.

Long poles 3 are arranged at equal intervals along the circumference on the yoke ring 1 of the salient pole rotor 2 of an electrical synchronous machine, e.g. a diesel generator. These each consist of a solid pole shaft 4 with a separately formed pole shoe 5, which can be solid or made of sheet metal and is welded to the solid pole shaft 4. The long poles 3 each carry the excitation winding required to excite the electrical synchronous machine.

Two shaft expansion screws 7 are used to fasten the long poles 3 to the yoke ring 1. These are located on the longitudinal axis of the long pole 3, symmetrically to the central connection 8 between the yoke ring 1 and the hub body 9 of the salient pole rotor 2, which is fastened to the rotor shaft 10.

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a GR90G4037 To accommodate the shaft expansion screws 7, through holes 11 are provided in the yoke ring 1 and corresponding through threaded holes 12 are provided in the pole shaft 4. These through threaded holes 12 can be easily manufactured and their entire height can be used as the screw-in length for the shaft expansion screw 7.

When screwed in, the shaft expansion screw 7 rests with its radially outer face 13 on the radially inner surface IA of the pole shoe 5, so that a gap that would hinder the transmission of the magnetic field within the long pole 3 is avoided. In order to achieve good centering of the shaft expansion screws 7, the expansion length 18 indicated by arrows between the threaded area 15 for screwing into the pole shaft 4 and the threaded area 16 for attaching the nut is selected to be smaller than the height of the yoke ring 1. A small threaded portion therefore protrudes from each side into the through hole 11 of the yoke ring 1, which forms a narrow gap to the through hole 11, which is dimensioned according to the thread diameter, and brings about centering. This prevents the long pole 3 from becoming jammed during assembly, which would result in additional gaps in the area of the excitation field.

To attach the long poles 3, the shaft expansion screws 7 are first screwed into the through-threaded holes 12 in the solid pole shaft 4 and then attached to the yoke ring 1 with the long pole 3, such that the shaft expansion screws 7 penetrate the through-holes 11.

It is then ensured that the radially outer face 13 of the shaft expansion screws 7 has come into contact with the radially inner face 14 of the pole shoe 5. Now the nut 17 is screwed onto the shaft expansion screw 7 and the expansion preload previously determined according to the centrifugal force loads occurring is applied, the size of which is determined by a

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5 GR 90G4037 screw 7, the strain gauge pin 19 indicated by dashed lines can be adjusted precisely.

In this position, the shaft expansion screw 7, which has a shoulder 21 formed as a polygon, e.g. as a hexagon, on the radially inner end face 20, is protected against accidental loosening by a locking plate 22, which is pushed over the shoulder 21 and screwed to the nut 17. The nut 17 is also secured to the yoke ring 1 in a known but not shown manner.

However, the fastening of the long poles 3 also allows for easy disassembly of the long poles, even if the salient pole rotor 2 is installed inside the stator of the synchronous machine (not shown). This is made easier by the front-side projection 21, through which the shaft expansion screw 7 can be easily unscrewed from the through-threaded hole 12 after the nut 17 has been removed, from the front side of the salient pole rotor 2.

In order to ensure that there is sufficient height available even when the distance between the yoke ring 1 and the hub body 9 is small, recesses 23 are provided in the hub body 9, which, designed like niches, correspond in position, number and dimensions to the shaft expansion screws 7 and are opposite their radially inner end faces 20. The shaft expansion screw 7 can therefore be turned down into these recesses 23 when loosening it for the purpose of dismantling the pole. The cross-section of the hub body 9 used for torque transmission is only weakened insignificantly by these recesses 23.

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Claims (4)

6 GR 90G4037 Protection claims 1. Electric synchronous machine with a salient pole rotor, the salient poles of which are designed as long poles each have a solid pole shaft and a separate pole shoe, which is attached to the yoke ring with at least two stud screws lying one behind the other in the longitudinal direction, each stud screw being screwed into a threaded hole in the pole shaft and its nut resting on the radially inner surface of the yoke ring, characterized in that a shaft expansion screw (7) is used as the stud screw, which, screwed into a through-threaded hole (12) in the pole shaft (4), rests with the radially outer end face (13) on the radially inner surface (14) of the pole shoe (5), and that the shaft expansion screw (7) has a projection (21) designed as a polygon on the other, radially inner end face (20), which is smaller than the thread diameter. 2. Electrical synchronous machine according to claim 1, characterized in that the expansion length (18) lying between the threaded areas (15, 16) of the shaft expansion screw (7) is smaller than the height of the yoke ring (1). 3. Electrical synchronous machine according to claim 1 or 2, characterized in that each long pole (3) is fastened to the yoke ring (1) by shaft expansion screws (7) arranged in pairs in the longitudinal direction symmetrically to the central connection (8) between the yoke ring (1) and the hub body (9) of the salient pole rotor (2). 4. Electrical synchronous machine according to claim 3, characterized in that recesses (22) are provided in the hub body, which, in each case in position, number and dimensions, correspond to the shaft expansion screws (7), and are located opposite the radially inner end face (20) of the latter. 02 01