DE102005038377A1 - Stator for e.g. single-phase six pole synchronous motor, has set of pole pairs, where one pole pair is formed without windings, and laminated core is provided with tooth per pole or group of teeth per pole - Google Patents

Abstract

The stator has a set of pole pairs, where one of the pole pairs is formed without windings. A main phase (12) and an auxiliary phase (14) are provided in the stator and the auxiliary phase is displaced opposite to the main phase at an angle of 120 degrees. A laminated core is arranged and number of pole pairs is provided as an integral multiple of three. The core is provided with a tooth (21) per pole or a group of teeth per pole. An independent claim is also included for a synchronous motor with a stator.

Description

The The invention relates to a stator for a synchronous motor and a synchronous motor with a stator and a rotor.

synchronous motors are well known. They generally have a stator and a rotor rotatably mounted therein, wherein so-called outer pole are known in which stator and rotor are reversed. At a Synchronous motor, the rotor has a constant magnetic field, which via a DC, via slip rings supplied will, or over Constant magnets is formed. The stator creates a circumferential Rotary field with which the rotor runs synchronously. The rotating field can be controlled by three-phase windings, which are formed on a magnetic field-conducting laminated core, be generated. Especially for smaller power synchronous motors and type also single-phase synchronous motors are used in which the circulating field over a main phase and an auxiliary phase is formed. The auxiliary phase becomes in this case, for example by means of a capacitor relative to the Phase out of phase, thereby forming the rotating field to be able to.

For example For example, a well-known single-phase synchronous motor has a rotor with four poles formed by constant magnets. Of the Stator has eight poles, four of which are poles through a main phase and four more poles alternating with the poles of the main phase an auxiliary phase are excited. Such synchronous motors have in Standstill good self-holding properties and are also similar to a stepper motor used. In connection with the good self-holding properties can However, disadvantages also occur due to reduced smoothness.

It is desirable a power increase at the same marginal operations, especially for the same size and the same Insulation class to achieve. An increase in performance is basically through for example, increase the pole pair number of the stator possible, however, this is for Accommodation of the necessary Winding the size is not retainable. About that In addition, increases require the number of pole pairs regularly one increase the production costs. On the other hand, especially with smaller synchronous motors, which are designed as single-phase synchronous motors, a cost-effective production crucial.

Known changes are thus to achieve an increase in performance under the same conditions little promising.

task The present invention thus provides an improved synchronous motor to create, if possible a power increase across from otherwise equivalent known single-phase synchronous motors achieved and / or possibly one has good running smoothness.

According to the invention, it is proposed for this purpose that the stator at least one substantially winding-free pole pair having. Thus, a circumferential field is achieved by at least one remaining pole pair. A winding-free pole pair can, for example, as a tooth pair of a Blechpaketes be formed, which thus despite missing own Direct excitation other parts of the magnetic fields of the engine leads. Such Magnetic fields can be caused by both excited stator poles and rotor poles. Thus, even such a winding-free pole pair the behavior of the engine.

Under essentially "winding-free" is to be understood that no excitation winding is provided. Smaller windings, in particular not provided for generating an excitation, but rather influence any edge effects, thus provide not to be regarded as essential winding. Also are the windings of adjacent pole pairs, which are thus immediately adjacent come to lie a substantially winding-free pole, this however, do not circle around, not as winding this winding-free Polpaares to understand. This is true even if the winding of a adjacent pole in the space of the winding-free pole extended can be by conventional Stators a winding for this winding-free pole would be provided.

Prefers a single-phase stator is used. Especially with single-phase Stators and thus single-phase synchronous motors is in contrast to three-phase synchronous motors the improvement of a stator of Meaning, because in synchronous three-phase motors more easily a symmetrical rotating field can be generated and above In addition, applications for Three-phase synchronous motors usually in relation to the engine volume lower requirements.

Cheap is if a stator has at least one major phase and at least one Auxiliary phase. Thus, at least one pair of poles with a main phase and at least one further pole pair excitable with an auxiliary phase. It can thus be generated a rotating field, in which the at least one essentially introduces non-winding pole pair.

Advantageously, a capacitive auxiliary phase, an inductive auxiliary phase or an elec used tronic commutation. In this way, a phase shift between the main and the auxiliary phase can be achieved in a simple manner. The design as a capacitive auxiliary phase or inductive auxiliary phase, in which a phase shift is essentially carried out by means of a capacitance or inductance, can be implemented in a simple, cost-effective and, in particular, low-maintenance manner. Sometimes an influence on the cosφ can be influenced. In electronic commutation, it is also possible to change a phase shift between the main and the auxiliary phase during operation.

conveniently, a phase shift occurs between the auxiliary and main phases around 120 °. This can be done by a phase shifter capacitor and additionally the Use of an opposite Wicklungssinns the respective windings are achieved. A such shift by 120 ° in the Operation of the synchronous motor is basically desirable, however depending on the operating state of the synchronous motor and thus by a few degrees, sometimes over 10 °, changeable. Thus, the parameterization of the wiring is something like this, that at the desired operating point there is a shift between auxiliary and main phase is done by about 120 °. In that regard, a shift of 120 ° between each pole of the main and auxiliary phase before, allowing for another pole, in particular a winding-free pole further shift by 120 °, So 240 ° to the Pole of the main phase is kept free. For lack of detailed measurements and / or simulations can currently only be suspected that an overlay the existing magnetic fields in the winding-free pole, for example 240 °.

According to one preferred embodiment is the number of pole pairs of the stator is an integer multiple of "3." It is favorable if every third pole is winding-free. As a result, an arrangement is possible at for example, in a circumferential direction of the stator Pole over a main phase is excited, the next pole over an auxiliary phase and then the third pole is winding-free. This basically results three poles or Polpaararten, in their operation and Circuitry - if available - on each other should be coordinated. In one case, therefore, the number of pole pairs would be exactly "3", so that a pole pair with main phase, one pole pair with auxiliary phase and one pole pair without Winding results. Likewise be provided six, nine or even more pole pairs, where at higher Polpaarzahl also increases the production cost.

In a preferred embodiment the stator has a laminated core with one tooth per pole or one Group of teeth per pole. The stator teeth can in principle have any shape and are in particular not on a rectangular Limited form. Through the laminated core is a lead reaches the magnetic field, the laminated core with his teeth as possible close up to the rotor to keep the air gap as small as possible. Of the Tooth or group of teeth leads the magnetic field of the respective pole. For this purpose is to generate the Magnetic field on a tooth or a group of teeth a field winding, in particular a main or auxiliary phase provided. It remains at least one tooth or group of teeth winding-free, with preference always one of three adjacent teeth or groups of teeth essentially is winding-free. As a result, a magnetic field is excited in one pole be through the laminated core to the other pole of the pole pair extends. In the same way, in one through an auxiliary phase Pol excited the magnetic field through the laminated core to the other pole headed by the pole pair. It is, however, assumed that both magnetic fields also at least partially over the at least one winding-free Pole pair extends. Thus, also in the winding-free poles assumed a magnetic field, at least partially from a superposition the other generated by main and auxiliary phases fields generated becomes. This could maybe to justify a contribution from non-developmental poles.

The Use of a group of teeth per Pol instead of a single tooth per pole may be advantageous to be able to direct the magnetic field in a targeted manner and / or a favorable transition the rotor poles when rotating from one stator pole to the next guarantee.

In In a particular embodiment, the stator teeth or groups of teeth are asymmetrical arranged to each other. This is especially beneficial for the windings preferably optimally arranged in the stator. In conventional stators is in the spaces between neighboring teeth of different Pole accommodated about the same amount of winding volume. However, according to the invention, some Poles have no windings, resulting in an uneven winding distribution in the stator, to which the stator can be adapted by the stator teeth or Groups of teeth are arranged asymmetrically to each other. Here is in particular, an asymmetry with respect to the rotor axis provided. For example, between two stator teeth, both windings carry more space than between two stator teeth, from which one carries no winding.

Preferably, a stator according to the invention is used for a synchronous motor with a rotor. The rotor and the stator are adapted to each other, and it is favorable when the pole Pair of the stator and the rotor are different. Such a configuration can have a favorable effect on the smoothness of the engine. In this case, it can be regarded as an advantageous embodiment that the number of pole pairs of the stator is "3" and that of the rotor is "2". For this case, a particularly simple embodiment, which also requires little manufacturing effort, since only two auxiliary and two main phase windings must be provided on the stator. Nevertheless, further combinations of Polpaarzahlen be used, such as three poles of the stator, four pole pairs of the rotor are provided.

Of the Rotor can be designed with or without iron core.

According to one another preferred embodiment is a synchronous motor characterized in that a permanent excited rotor is provided, wherein the rotor poles substantially made of hard ferrite, rare earth, plastic-bound rare earths or other permanent magnetic material. Just in the field of smaller synchronous motors used as single-phase synchronous motors are configured, is a excitation of the rotor over a direct current too complex, so that a permanent-magnet rotor is used. In addition, especially with smaller ones Motors, but not only here, the use of a permanent magnet Rotor sufficient. The permanent arousal can be through hard ferrite or even rare earth magnets. Just the use of rare earths can be used to reach a rotor pole with high magnetic field strength be displayed. To improve the mechanical stability is sometimes the use of plastic-bound rare earths advantageous. A limitation However, these materials are not, but rather in principle any permanent magnetic materials alone or in addition to the construction the rotor can be used.

The The present invention will be described below with reference to a figure. The

1 shows a schematic diagram of the coil arrangement of a synchronous motor according to the invention, which is shown schematically for this purpose in a section transverse to the rotor axis.

The synchronous motor 2 of the 1 has a stator 4 and a rotor 6 on. The stator 4 includes a laminated core 8th with six stator teeth 21 - 26 , The number of pole pairs of the stator is thus "3." The stator is designed in a single-phase, one main phase 12 and an auxiliary phase 14 are provided. The routing for the main and auxiliary phases 12 . 14 , in particular the windings themselves, are shown only schematically in the figure. Even with a stator according to the invention a plurality of turns per pole are regularly used.

The main phase 12 is connected between the phase P and neutral N and energized across the windings 31 and 34 on the stator teeth 21 respectively. 24 a magnetic field substantially in these stator teeth thereby forming the poles. In this case, a magnetic field forms from the stator tooth 21 out over the rotor 6 to the stator tooth 24 that is about the body of the laminated core 8th closes.

The auxiliary phase 14 is via interconnection by means of a capacitor 16 to the main phase 12 educated. About the dimensioning of the capacitor 16 the phase shift can be influenced compared to the main phase. The excitation current of the auxiliary phase 14 excited about the windings 32 and 35 on the stator teeth 22 and 25 a magnetic field in these poles. The winding 32 the auxiliary phase faces the winding 31 the main phase an opposite winding sense. In principle, this results in a phase shift of the two in the stator teeth 21 and 22 excited magnetic fields by 180 °. By a phase shift of the current of the auxiliary phase 14 towards the main phase 12 around 60 °, which is due to the capacitor 16 can be achieved, a shift of said magnetic fields by 120 ° against each other achievable. It should be noted that the displacement is also influenced by the operation of the engine. Also results in accordance with a phase shift of the excited magnetic fields between the poles of the stator teeth 25 and 24 through the windings 35 and 34 ,

The stator teeth 23 and 26 do not have a winding. The magnetic field that is in these stator teeth 23 and 26 thus depends only on the magnetic fields that are excited by the main and auxiliary phases and by influences that are caused by the rotor. Although so far no concrete magnetic field measurements of the winding-free poles, in this case by the stator teeth 23 and 26 have been carried out, it can be assumed that a magnetic field is also formed in these non-conducting poles. In this context, it is pointed out that, for example, results from a superposition of two mutually shifted by 120 ° sinusoidal waveforms of the same amplitude about a further 120 ° shifted course. In that regard, also for the winding-free poles in the stator teeth 23 and 26 with one for operating the synchronous motor 2 favorable magnetic field or at least a favorable influence of the magnetic field.

The rotor 6 of the synchronous motor 2 has two north poles N and two south poles S, so that the number of pole pairs of the rotor is "2." Due to the different number of pole pairs between stator and rotor has the effect that each have a north pole N adjacent to a stator tooth 21 ; 24 lies, while in each case a south pole S between two stator teeth 22 . 23 ; 25 . 26 come to lie. Upon further rotation of the rotor 8th The south poles S each move toward a stator tooth, while the north poles N move to a position between two stator teeth, respectively. This can result in favoring the smoothness.

The The present invention thus provides a stator for a Synchronous motor, in which at least one pole pair is winding-free. This allows a single-phase motor using a main and an auxiliary phase having a six-pole stator.

Claims (14)

Stator ( 4 ) for a synchronous motor ( 2 ) having a plurality of pole pairs, characterized in that at least one pair of poles is formed substantially free of winding. Stator ( 4 ) according to claim 1, characterized in that it is designed single-phase. Stator ( 4 ) according to claim 1 or 2, characterized by at least one main phase ( 12 ) and at least one auxiliary phase ( 14 ). Stator ( 4 ) according to one of the preceding claims, characterized in that a capacitive auxiliary phase ( 14 ), an inductive auxiliary phase or an electronic commutation is provided. Stator ( 4 ) according to one of the preceding claims, characterized in that an auxiliary phase ( 14 ) compared to a main phase ( 12 ) is shifted by about 120 °. Stator ( 4 ) according to one of the preceding claims, characterized in that the number of pole pairs is an integer multiple of 3. Stator ( 4 ) according to one of the preceding claims, characterized in that every third pole is winding-free. Stator ( 4 ) according to one of the preceding claims, characterized by a laminated core ( 8th ) with a tooth ( 21 - 26 ) per pole or group of teeth per pole. Stator ( 4 ) according to one of the preceding claims, characterized in that always one of three adjacent teeth ( 21 - 26 ) or groups of teeth is essentially winding-free. Stator ( 4 ) according to one of the preceding claims, characterized in that the stator teeth ( 21 - 26 ) or groups of teeth are arranged asymmetrically to each other. Synchronous motor ( 2 ) with: - a stator ( 4 ) according to one of the preceding claims and - with a rotor ( 6 ). Synchronous motor ( 2 ) according to claim 11, characterized in that the pole pair number of the stator ( 4 ) and the rotor ( 6 ) are different. Synchronous motor ( 2 ) according to claim 11 or 12, characterized in that the pole pair number of the stator ( 4 ) "3" and that of the rotor ( 6 ) Is "2". Synchronous motor ( 2 ) according to one of claims 11 to 13, characterized in that a permanent-magnet rotor ( 6 ), wherein the rotor poles (N, S) essentially consist of hard ferrite, rare earths, plastic-bound rare earths or another permanent magnetic material.