DE102011081035A1 - Electric machine - Google Patents

Abstract

The invention relates to a brush-commutated electric machine (1), comprising: - a rotor (6) with a number of rotor teeth (8); - Rotor coils (10), each enclosing one or more of the rotor teeth (8); A stator arrangement with stator poles which have at least one permanent magnet stator pole (4) formed with a permanent magnet (3) and at least one follower pole (5) not provided with a permanent magnet, which are arranged in a follower pole arrangement; A commutator having at least one pair of brushes for contacting a armature coil group of interconnected armature coils, the total inductance of the interconnected armature coils (10) of one of the armature coil groups at first and second positions of the armature (6) being equal with respect to the stator assembly ,

Description

Technical area

The invention relates to brush-commutated electrical machines in which the stator has a follower pole arrangement. In particular, the present invention relates to a winding scheme for a rotor of such an electric machine.

State of the art

Brush-commutated direct current motors are known in the prior art in many different variants. In particular, internal rotor motors find a variety of applications.

A common variant of an internal rotor DC motor is, for example, from the publications US 4,372,035 and DE 10 2009 033 623 A1 known. These documents each show an electric motor with a four-pole stator arrangement, in which the stator poles are formed by two mutually opposite with respect to the axis of rotation of the inner rotor permanent magnets of the same polarity (permanent magnet stator poles) and two not provided with permanent magnets pole pieces (follower poles) in a follower pole. Such a follower pole arrangement basically has the advantage that the number of permanent magnets compared to electric motors, in which each stator pole is formed with a permanent magnet, is reduced.

The rotor for one of the above-mentioned electric motors has a rotor winding with a plurality of rotor coils, which are contacted for energizing via a commutator. Usually, the armature coils are designed as winding loops, wherein each winding loop encloses two or more than two rotor teeth or one or more rotor slots arranged between the rotor teeth and is contacted via spaced apart from brushes of a brush pair commutator. In order to achieve a rapid reversal of the winding loop, each winding loop can also be short-circuited via two commutator segments that are directly adjacent to one another. In order to increase the number of simultaneously energized winding loops, a plurality of brush pairs may be provided for contacting the commutator segments. Since the brushes have a fixed arrangement with respect to the permanent magnet stator poles, they always contact only winding loops that are in the same position with respect to the stator.

In the above arrangement of the rotor coils, the rotor coils are short-circuited after their energization by a corresponding brush, which simultaneously covers two adjacent Kommutatorlamellen when moving the rotor, to first reduce a current flowing due to a voltage induction current. This is due to the fixed position of the brush always at certain positions of the rotor coils. Therefore, the shorting of a winding loop by a certain brush always occurs at a certain position of the respective winding loop. Ie. a brush always closes the winding loops short when they are aligned in a certain position to the stator poles.

When using a follower pole arrangement, however, the inductance of the armature coils varies depending on whether the rotor tooth on which the relevant armature coil is arranged is in a position in which it is aligned with a permanent magnet stator pole or a follower pole. The inductance of the rotor coils aligned with the follower poles is significantly greater than the inductance of the rotor coils aligned with the permanent magnet stator poles due to the small effective size of the air gap. Therefore, one brush short-circuits the winding loops if they are at least predominantly aligned with the permanent magnet stator poles, and another brush short-circuits the winding loops if they are at least predominantly aligned with the following poles.

However, a high inductance degrades the commutation and produces stronger sparking at the corresponding commutator brushes that turn winding loops with a higher inductance (which tends to face the follower poles) than do commutator brushes that have lower inductance winding loops (tend to face the permanent magnet poles). short. The sparking favors the wear of the commutator. Due to the fixed assignment of the brushes to the position of the energized rotor coils, therefore, there is an uneven wear of the brushes. In particular, the brushes that short-circuit rotor coils around rotor teeth that are aligned with the follower poles are thereby exposed to increased wear.

As a result of the uneven wear, an asymmetrical contact behavior on the commutator can occur so that unwanted force or noise excitations can also occur.

It is therefore an object of the present invention to provide an electrical machine with a follower pole arrangement, in which an uneven wear of the commutator brushes is reduced or avoided.

Disclosure of the invention

This object is achieved by the electric machine with a follower pole arrangement of the stator poles according to claim 1.

Further advantageous embodiments of the present invention are specified in the dependent claims.

• – einen Läufer mit einer Anzahl von Läuferzähnen;
• – Läuferspulen, die jeweils einen oder mehrere Läuferzähne umschließen;
• – eine Statoranordnung mit Statorpolen, die mindestens einen mit einem Permanentmagneten gebildeten Permanentmagnet-Statorpol und mindestens einen nicht mit einem Permanentmagneten versehenen Folgepol aufweisen, die in einer Folgepolanordnung angeordnet sind;
• – einen Kommutator mit mindestens einem Bürstenpaar, um eine Läuferspulengruppe von miteinander verschalteten Läuferspulen zu kontaktieren,

wobei jeweils die gesamte Induktivität der verschalteten Läuferspulen einer der Läuferspulengruppe an einer ersten und an einer zweiten Stellung des Läufers bezüglich der Statoranordnung gleich ist.According to a first aspect, there is provided a brush-commutated electric machine comprising:

• A runner with a number of runner teeth;
• - Rotor coils, each enclosing one or more rotor teeth;
• A stator arrangement having stator poles which have at least one permanent-magnet stator pole formed with a permanent magnet and at least one follower pole not provided with a permanent magnet, which are arranged in a follow-up pole arrangement;
• A commutator having at least one brush pair to contact a rotor coil group of interconnected armature coils,

wherein each of the total inductance of the interconnected armature coils of one of the armature coil group at a first and at a second position of the rotor is the same with respect to the stator assembly.

An idea of the invention is that any brush that contacts a rotor coil group in a particular position with respect to the stator poles will switch an equal or approximately equal inductance during commutation. This applies both to the inductance switched by brushes of the brush pair and to the armature coil group short-circuited by each of the brushes when passing adjacent commutator blades. As a result, a symmetrical contact behavior can be achieved, whereby the wear of the commutator bars or the brushes is uniform. An undesirable force or noise excitation by fluctuations in the wear of the brush or the fins can be avoided.

Further, the armature coils of the armature coil group may be connected to each other in a series connection, a parallel connection, or a combination thereof.

According to one embodiment, the armature coils of the armature coil group may have a first follower coil aligned with a follower pole and a second rotor coil aligned with a permanent magnet stator pole at a position of the armature relative to the stator assembly.

In particular, the first and second rotor coils of the armature coil group may have a different winding sense.

Furthermore, the first and second rotor coils of the armature coil group may be offset from each other by an offset angle that is an angle of (2k + 1) · 360 ° / N where k = 0, 1, ..., N / 2 - 1 corresponds, where N corresponds to the number of stator poles.

Alternatively, the first and second rotor coils of the armature coil group may be offset from one another by an offset angle that is an angle of (2k + 1) · 360 ° / N +/- 180 ° / M with k = 0, 1, ..., N / 2 - 1 where N is the number of stator poles and M is the number of rotor teeth.

It can be provided that the first and the second rotor coil have different numbers of turns.

Furthermore, it can be provided that the first and the second rotor coil enclose different numbers of rotor teeth.

Brief description of the drawings

Preferred embodiments of the present invention will be explained in more detail with reference to the accompanying drawings. Show it:

1 a schematic cross-sectional view through an electric motor with a follower pole arrangement;

2 a winding scheme with two serially interconnected rotor coils, which are connected to adjacent commutator bars;

3 a representation of a rotor coil group of two serially interconnected rotor coils, which are offset with respect to the rotor by 90 ° to each other;

4 a representation of a rotor coil group with serially interconnected rotor coils in a ten-pole rotor;

5 a representation of another way of interconnecting a rotor coil group with serially interconnected rotor coils in a ten-pole rotor;

6 a representation of a rotor coil group with serially interconnected rotor coils with a connection of the rotor coils on the opposite side of a commutator; and

7 a representation of a rotor coil group with serially interconnected armature coils with different winding steps.

Description of embodiments

1 shows a schematic cross-sectional view of an electric motor 1 (electric machine), with a pole housing 2 on which a plurality of stator poles are provided. Inside the pole housing 2 An interior recess is provided in which a runner 6 is rotatably mounted on a shaft. The stator poles are on the pole housing 2 arranged so that these in the direction of the inner recess or in the direction of the rotor 6 point.

The stator poles are as a permanent magnet stator pole 4 and not with a permanent magnet 3 provided follower pole 5 educated. The pole housing 2 is preferably formed of a magnetically conductive material so as to pass over the pole housing 2 a magnetic closure (magnetic connection) between the permanent magnet stator pole 4 and the follower pole 5 train. The number N of stator poles 4 . 5 however, it is not limited to four but may be any even number of stator poles 4 . 5 be provided.

The runner 6 has a magnetically conductive armature 7 with a number of runner teeth 8th in, in the embodiment shown ten rotor teeth, each of one or more rotor coils 10 a rotor winding are enclosed. The wave of the runner 6 carries axially to the anchor 7 puts a commutator with a number of commutator bars 11 which is essentially the number of rotor teeth 8th corresponds, in the illustrated embodiment 10. The commutator bars 11 Be about two, three or more brushes 12 or several brush pairs contacted. The commutator bars 11 are connected to the rotor coils of the rotor winding in the form of a loop winding, ie each commutator 11 is in each case via one or more rotor coils with two adjacent commutator segments 11 connected.

In 2 is schematically an arrangement of rotor coils 10 on two adjacent commutator bars 11 shown. Although the commutator and the runner teeth 8th In the embodiment shown are arranged in a circle, is here for reasons of clarity, the rectilinear representation of the commutator 11 , the brush 12 , the runner teeth 8th and the rotor coils 10 selected. In the example shown so the rotor tooth 1 and the runner tooth 10 and the commutator blade 1 and the commutator blade 10 adjacent to each other.

In the shown electric motor 1 are brushes 12 provided by two pairs of brushes, via each of which a supply voltage is applied to a respective rotor coil group of stator coils 10 to energize. Due to the stationary positioning of the brushes 12 The brushes are the position of the energized rotor coils 10 or the area in which the rotor coils 10 are fixed when energized. This is because the winding scheme is generally selected rotationally symmetric, so that comparable Bestromungssituationen each after one or more movement steps of the rotor to the width of a commutator 11 consist.

If more of the rotor coils are due to a first of the pairs of brushes 10 on to a follow-up pole 5 aligned rotor teeth 8th be energized as by a second of the pairs of brushes, so are the operation of the electric motor 1 the brushes 12 of the first brush pair due to their higher inductance exposed to higher wear than the brushes 12 of the second brush pair.

Furthermore, the commutator bars 11 in a suitable manner electrically connected to each other, so that in each case two adjacent commutator bars 11 through one of the two commutator bars 11 energized armature coil group of stator coils 10 short-circuited if the brush brushes over it. This makes it possible the rotor coil group of stator coils 10 short before the polarity reversal so that the supply voltage does not have to be applied against a voltage induced in the armature coil group. Because of the fixed arrangement of the brushes 12 the armature coil group of stator coils 10 is always shorted at the same position by a respective brush, it also comes due to the position-dependent inductors of the rotor coil groups to different wear of the brushes 12 by sparking and the like.

In order to reduce or eliminate these effects, it is now provided that rotor coil groups are each supplied with the same inductances by the brush pairs, or rotor coil groups with the same inductances are short-circuited by the individual brushes. The positions of the rotor coils are 10 a rotor coil group selected so that their wrapped rotor teeth 8th alike alike, ie, for example, in each case the same number, the permanent magnet stator poles 4 and the following poles 5 assigned. In this way, all brushes contact 12 the same overall inductance, so that the wear the brushes 12 is substantially the same and thus no significant wear-related resistance changes in the contacting of commutator 11 through the brushes 12 may occur.

Since the permanent magnet stator poles 4 and the followers 5 have a different magnetic polarity, it is provided that the winding sense of the one or more follower poles associated rotor coils and the winding sense of the one or more permanent magnet stator poles associated rotor coils is opposite to each other. As a result, magnetic fields of different directions are generated as excitation magnetic fields with common energization.

The rotor coils 10 a rotor coil group are connected in series with each other in the embodiment shown. Parallel interconnections of the armature coils simultaneously contacted via the commutator or combinations of parallel and serial interconnections are more than two armature coils 10 a rotor coil group conceivable.

It is also possible that an odd number of rotor coils 10 per rotor coil group is provided, it must be ensured that the entire inductance, resulting from the interconnection of the subsequent poles 5 associated rotor coils 10 and the permanent magnet stator poles 4 associated rotor coils 10 gives, in equal parts of the following poles 5 associated rotor coils 10 and the permanent magnet stator poles 4 associated rotor coils 10 is effected. In general, no inductance change is to occur when the rotor makes a movement about the distance of a stator pole, so that the previously the subsequent poles 4 associated rotor coils 10 now the permanent magnet stator poles 4 are assigned and vice versa. If the same rotor coil arrangement is contacted by the further brush pair after further movement of the rotor, the assignments of the rotor coils are 10 vice versa to the respective stator poles.

Preferably, a first armature coil and a second armature coil of the armature coil group of jointly contacted armature coils are arranged offset relative to one another on the armature such that they correspond to the offset between a follower pole 5 and a permanent magnet stator pole 4 the stator arrangement, in particular an adjacent permanent magnet stator pole 4 correspond. In the above stator arrangement with four stator poles, the offset corresponds to 90 °. Generally, the offset corresponds to 360 ° / N, where N equals the total number of stator poles of the follower pole array. In general, the offset between the armatures of the armature coil group associated with different stator poles can be given as: (2k + 1) · 360 ° / N where k = 0, 1, ..., N / 2 - 1

In 3 schematically for a twelve-pole rotor is a series connection of contactable via one of the pairs of brush rotor coils 10 shown. With the help of a pair of brushes, interconnected rotor coils are connected in series 10 energized, with a first of the rotor coils 10 one of the follower poles 5 and a second of the rotor coils 10 a permanent magnet stator pole adjacent thereto 4 assigned. This results in a series inductance which corresponds to the sum of the different individual inductances.

The arrangement of the armature coil group of armature coils contacted by another of the pairs of brushes 10 is appropriate. By this arrangement of the rotor coils 10 is the series connection at a further rotation of the rotor 6 through the brushes 12 the further brush pair contacted, in which case the first rotor coil 10 a permanent magnet stator pole 4 and the second rotor coil 10 a follower pole 5 are assigned, ie the assignment is therefore reversed. The entire inductance of the series connection of the rotor coil 10 remains unchanged. In this way, it is possible to apply only the same inductances when commutating using brushes, so that no uneven wear of the brushes 12 can occur.

Leaves the number M of rotor teeth 8th of the runner 6 an offset of the rotor coils arranged in a rotor coil group 10 not to 360 ° / N, so also a slightly different offset can be selected, as for example in the 4 and 5 for the 10-pole armature of the rotor with the four-pole stator of the electric motor of 1 the case is. There the calculated offset between the rotor coils N / M of a rotor coil group would correspond to 2.5 rotor teeth / rotor grooves.

If an integer division of the number M of rotor teeth / rotor slots by the number N of stator poles is not possible, a slot division is necessary in which the coil spacing of the series-connected rotor coils exceeds 360 ° / N (see FIG 4 ) or less than 360 ° / N (see 5 ) corresponds. In case of 10 Rotor poles can then be arranged the rotor coils at a distance of 90 ° plus 180 ° / M or 90 ° minus 180 ° / M. However, it is desirable that rotor coils enclosing a rotor groove or more than one rotor tooth include the exact offset of (2k + 1) * 360 ° / N.

In 6 an embodiment is shown, which differs from the embodiment of the 3 this differs in that the electrical connection between the armature coils 10 the armature coil group on the commutator axially opposite side of the anchor 7 is carried out. It is also shown that the number of turns of the first and second rotor coils 10 can be different.

As in 7 shown, it is also possible to different winding steps for the two series-connected rotor coils 10 to provide, ie the rotor coils 10 A rotor coil group may have different numbers of rotor grooves or rotor teeth 8th enclose.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• US 4372035 [0003]
• DE 102009033623 A1 [0003]

Claims (9)

Brush-commutated electric machine ( 1 ), comprising: - a runner ( 6 ) with a number of rotor teeth ( 8th ); - rotor coils ( 10 ), each one or more of the rotor teeth ( 8th ) enclose; A stator arrangement with stator poles, which has at least one with a permanent magnet ( 3 ) formed permanent magnet stator pole ( 4 ) and at least one not provided with a permanent magnet follower pole ( 5 ) disposed in a follower pole array; A commutator having at least one pair of brushes for contacting a rotor coil group of interconnected armature coils, the total inductance of the interconnected armature coils ( 10 ) one of the armature coil group at a first and at a second position of the runner ( 6 ) is the same with respect to the stator assembly. Electric machine ( 1 ) according to claim 1, wherein one of the rotor coils ( 10 ) of the armature coil group in the first position to a follower pole ( 5 ) and in the second position on a permanent magnet stator pole ( 4 ) is aligned. Electric machine ( 1 ) according to claim 1 or 2, wherein the rotor coils ( 10 ) of the armature coil group are connected in a series connection, a parallel connection or in a combination thereof with each other. Electric machine ( 1 ) according to one of claims 1 to 3, wherein the rotor coils ( 10 ) of the armature coil group at a position of the runner ( 6 ) with respect to the stator arrangement, a first to a follower pole ( 5 ) aligned rotor coil ( 10 ) and a second to a permanent magnet stator pole ( 4 ) aligned rotor coil ( 10 ) exhibit. Electric machine ( 1 ) according to claim 4, wherein the first and second rotor coils ( 10 ) of the armature coil group have a different winding sense. Electric machine ( 1 ) according to claim 4 or 5, wherein the first and second rotor coils ( 10 ) of the armature coil group are offset from each other by an offset angle which is an angle of (2k + 1) · 360 ° / N where k = 0, 1, ..., N / 2 - 1 corresponds, where N corresponds to the number of stator poles. Electric machine ( 1 ) according to claim 4 or 5, wherein the first and second rotor coils ( 10 ) of the armature coil group are offset from each other by an offset angle which is an angle of (2k + 1) · 360 ° / N +/- 80 ° / M with k = 0, 1, ..., N / 2 - 1 where N is the number of stator poles and M is the number of rotor teeth ( 8th ) correspond. Electric machine ( 1 ) according to one of claims 4 to 7, wherein the first and second rotor coils ( 10 ) have different numbers of turns. Electric machine ( 1 ) according to one of claims 4 to 8, wherein the first and second rotor coils ( 10 ) different numbers of rotor teeth ( 8th ) enclose.

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