DE2745516A1 - Rotary electric machine with reduced armature reaction - has pole laminations interleaved with non-magnetic material for flux to encounter high magnetic reluctance - Google Patents

Abstract

The rotary electric machine includes laminations in the poles and yokes associated with the energising windings. The laminations are arranged to be parallel to the axis of rotation and are interleaved with non-magnetic or poorly magnetic material. Thus in order to reduce armature reaction the laminations are so arranged that the magnetic flux which is provided by armature current flow encounters a high magnetic reluctance. Armature reaction may be further reduced by leaving a space between adjacent halves of the poles. This construction is also applicable to machines with commutating poles.

Description

Description and claims

Arrangement to reduce armature feedback in rotating electrical Machines With commutator machines (for direct or single-phase alternating current) and with Synchronous machines, armature feedback is a fundamental problem Flux created by the anchor flow in the machine causes a distortion and as a result of saturation phenomena also a weakeningX of the excitation field, what again a voltage loss in the armature circuit or, viewed overall, a loss in machine performance. The aim is therefore to reduce the anchor reaction to be kept within tolerable limits. For this reason, for example, the aforementioned Machines designed with a much larger air gap between the main pole and armature, than would be necessary for purely mechanical reasons. However, this makes a bigger one Excitation flow required, which in turn increases the size of the machine is conditioned. This of course also makes the machine more expensive.

The key idea of the present invention to reduce the Armature feedback from rotating electrical machines is that accordingly Fig. 1 the iron sheets (1) in the poles (2) and yokes (3) of the excitation winding (4) supporting machine part (exciter part) arranged parallel to the axis of rotation and in each case by non-magnetic or magnetically only weakly conductive Material (5) are separated from each other and guided separately, so that of the Armature flow (6) in the exciter part caused magnetic flux in this exciter part finds a high magnetic resistance.

In order to form a magnetic return path, the invention is used built-up iron core of each pole according to FIG. 2 at the pole core root 7. Split in half in the direction of the axis of rotation and each half for as a yoke (3) continuously to one of the two adjacent poles. If necessary, the iron sheets (1) on the pole piece (8) are made according to the desired Pole coverage ratio spread and held in this position. Here you can materials are also used for the iron sheets, which have a preferred magnetic direction have in the direction of the field line path of the pathogen flow.

Furthermore, the iron sheets (1), as shown in Fig. 3, for example, already in the course of their manufacture with non-magnetic or magnetic only weakly conductive material (5) of the required thickness are coated, so that they are only stacked on top of one another, glued together in the manner according to the invention and formed into an exciter sub-segment (9), for example according to FIG. 2 Need to become.

An additional possibility, the anchor retroactive effect Further to reduce, is that between the two iron core halves (10) one each main pole according to FIG. 4 a distance (11) is maintained, which is greater than the given distance between the individual sheets in this area and that the distance between the two iron core halves of each main pole either kept empty or with non-magnetic or magnetically only weakly conductive The typical induction curve (12) in the air gap (16) of a Main poles constructed in this way are shown in the lower part of FIG. Included with (13) the field exciter curve of the armature, with (14) that of the armature flow alone (6) and with (15) the induction curve originating solely from the excitation flow (4) marked in the air gap (16).

Reversing poles can also be used in a machine constructed according to the invention are provided. One of the possible exemplary embodiments is shown in FIG. 5. Here, the reversible pole (17) composed of two subsegments (18), which in the drawn Kind are arranged within the main pole segment. The reversal flow closes then in contrast to the classic design of the machine no longer over the The pole core root of the neighboring main pole but across the air gap between them Armature and the end of the turning pole segment facing the respective main pole. Included the reversible pole segments can be designed in the same way as the main pole segments will, whereby the distance between the reversible iron sheets is also smaller or too large Zero can be chosen. Furthermore, the reversible pole segments can be solid and the mutually associated parts of each reversible pole, if necessary, to one single part can be summarized. With the latter, the transition is then also open a sheet metal design perpendicular to the axis of rotation possible. Another embodiment Fig. 6 shows the reversible poles. Here, the reversible pole system (19) is in solid or laminated design on one side in an axial extension to the main pole system (20) arranged, in such a way that the turning poles (17) in the axial extension of the gaps between each two main poles. Another possibility is to arrange such a reversible pole system (19) on both sides of the main pole system (20). The opposite poles of the same name can then still go through Magnetically highly conductive webs are connected, which in this way the pole shoes of effective reversing poles along the entire active armature length.

The schematic structure of a DC machine designed according to the invention Fig. 7 shows without reversing poles.

In Fig. 8 is an internal pole synchronous machine constructed according to the invention Rotor (21) shown. The anchor reaction in the transverse axis and thus the associated synchronous reactance is much smaller here than with a normal one Machine.

All of the above arrangements can be beveled or not Rotors and / or stators are executed.

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Claims (25)

Claims arrangement for reducing anchor reaction in electrical machines, characterized in that to reduce the Magnetic armature flux in rotating electrical machines Flow, which is the component that is firmly coupled with the excitation flow, the so-called Excitation part or excitation system, interspersed, the iron sheets in the pole pieces, pole cores and yokes of the exciter part arranged parallel to the axis of rotation and each through non-magnetic or magnetically only weakly conductive materials so far separated from each other and are performed separately that the caused by the armature flow in the exciter part magnetic flux in this exciter part in all possible ways there finds very high magnetic resistance. 2. Arrangement according to claim 1, characterized in that the iron core of each pole at the pole core root in the direction of the axis of rotation in two halves is divided and each half for itself as a yoke continuously to one of the two adjacent pole is guided. 3. Arrangement according to claim 1, characterized in that the iron core of each pole at the pole core root first in the direction of the Axis of rotation is divided into two halves and that these halves, turn into Direction of the axis of rotation in a larger, in the direction of the pole core center, and are divided into a smaller part remote from the center of the pole core and that the said larger parts each as a yoke continuously to one each of the two adjacent poles are guided and that the two smaller parts each are led up to the middle of the next pole gap and come together there with the smaller part coming from the opposite pole the core of a form so-called reversing poles. 4. Arrangement according to claim 3, characterized in that the through non-magnetic or magnetically only weakly conductive materials filled spaces between the iron sheets of the smaller ones belonging to the magnetic circuit of the turning poles Parts of the excitation system are kept smaller than the distances between the iron sheets of the larger parts belonging to the magnetic circuit of the main poles of the pathogen system exist. 5. Arrangement according to claim 3, characterized in that the distances between the iron sheets of the smaller ones belonging to the magnetic circuit of the turning poles Parts of the pathogen system as small as constructively in a simple way can be kept realizable. 6. Arrangement according to claim 3, characterized in that the for magnetic circuit of the reversing poles belonging to smaller parts of the excitation system unleaded and are made of solid, magnetically highly conductive material. 7. Arrangement according to claim 6, characterized in that the two parts of each reversing pole leading to the center of the pole gap become a mechanical one and magnetically fixed part are joined together. 8. An arrangement according to claim 7, characterized in that the for parts of the excitation system belonging to the magnetic circuit of the reversing poles are not massive, rather, they are laminated perpendicular to the axis of rotation. 9. Arrangement according to claim 1 to 5, characterized in that for the Etsenbleche preferably materials with a preferred magnetic direction in the direction the field line path of the excitation flow and the reversing pole flow can be used. 10. Arrangement according to claim 6 to 8, characterized in that for the iron sheets of the part of the excitation system belonging to the magnetic circuit of the main poles preferably materials with a preferred magnetic direction in the direction of the field line path of the excitation flow can be used. 11. Arrangement according to one of claims 1 to 10, characterized in that that a distance is maintained between the two iron core halves of each main pole which is greater than the given distance of the individual in this area Sheets of the two iron core halves one below the other and that the distance between the both iron core halves of each main pole kept empty or with non-magnetic or magnetically only weakly conductive material is filled. 12. Arrangement according to one of claims 1 to 11, characterized in that that the iron sheets on the pole shoe in a the desired pole coverage ratio resulting spread position are held. 13. Arrangement according to one of claims 1 to 12, characterized in that that Iron sheets are used, which are already in the course of their manufacture with non-magnetic or magnetically only weakly conductive material required at the point in question Thickness have been coated. 14. Arrangement according to claim 1 or 2, characterized in that the part of the excitation system belonging to the magnetic circuit of the reversing poles in massive or laminated design on one side in the axial extension of the magnetic Part of the excitation system belonging to the circle of the main poles, in such a way that that the turning poles in the axial extension of the gaps between each two main poles lie. 15. Arrangement according to claim 1 or 2, characterized in that on both sides of the part of the excitation system belonging to the magnetic circuit of the main poles a reversing pole system is arranged according to claim 14, its eponymous Poles face each other in the axial direction. 16. The arrangement according to claim 15, characterized in that the in axial direction opposite, same-named reversing poles by magnetically Well conductive webs are connected, which so the pole pieces of on the whole active armature length to form effective reversing poles. 17. Arrangement according to one of claims 14 to 16, characterized in that that for the iron sheets of the part belonging to the magnetic circuit of the main poles of the excitation system, preferably materials with a preferred magnetic direction in Direction of the field line path of the excitation flow can be used. 18. Arrangement according to one of claims 14 to 16, characterized in that that a distance is maintained between the two iron core halves of each main pole which is greater than the given distance of the individual in this area Sheets of the two iron core halves one below the other and that the distance between the both iron core halves of each main pole kept empty or with non-magnetic or magnetically only weakly conductive material is filled. 19. Arrangement according to one of claims 14 to 16, characterized in that that the iron sheets on the pole shoe in a the desired pole coverage ratio resulting sprayed Are kept. 20. Arrangement according to one of claims 14 to 16, characterized in that that iron sheets are used, which are already in the course of their manufacture with non-magnetic or magnetically only weakly conductive material required at the point in question Thickness have been coated. 21. Arrangement according to one of claims 1 to 20, characterized in that that the excitation system of commutator machines for direct and single-phase alternating current is carried out according to this principle. 22. Arrangement according to one of claims 1 and 2 and 10 to 13, characterized characterized in that the exciter part of Synchronmascliinen executed according to this principle is. 23. Arrangement according to one of claims 1 to 22, characterized in that that the laminated rotor core is relative to the stator or has a slope to the rotor axis. 24. Arrangement according to one of claims 1 to 22, characterized in that that the stator core is relative to the rotor axis has a bevel. 25. Arrangement according to one of claims 1 to 22, characterized in that that the rotor and stator laminations are opposite to each other relative to the rotor axis Have bevels.