DE19956367A1 - Heteropolar stimulated reluctance machine has transverse arrangement of magnetic stimulation circuits in peripheral direction closed by air gap between teeth on stator and rotor - Google Patents

Abstract

The machine has a stator (1) with teeth extending on the air gap side and carrying stimulation and phase windings. The stimulation windings defines stimulation poles for the stator divided into first and second sub-poles in the peripheral direction with intervening pole gaps. A coil-less rotor (3) has peripherally uniformly distributed teeth. The stator teeth distribution inside the sub-poles corresponds to that of the rotor teeth. A transverse arrangement of magnetic stimulation circuits in the peripheral direction are closed by the air gap (5) between a tooth on the stator and a tooth on the rotor.

Description

The invention relates to a heteropolar excited reluctance machine, consisting of a stator provided with axially extending teeth on the air gap side, the Er excitation and phase windings, the excitation winding excitation poles of the Sta tors defined in the circumferential direction in a first and a second Partial pole with the pole gap in between are subdivided and the pole gap one circumferential offset of the teeth of the second to the first partial pole causes, and consists of a windingless rotor, the air gap side in Um direction is uniformly provided with axially extending teeth, wherein the tooth pitch of the stator teeth within the partial poles of the rotor teeth ent speaks.

The field of application of the invention relates in particular to higher lei relatively slow-running electrical machines, d. H. Engines and generators, in which on the interposition of a transmission from under for various reasons. Examples are by hydropower or Generators driven by wind energy or winch and vehicle drives.

When using conventional synchronous machines in low speed ranges either the arrangement of a gear (with all associated disadvantages) required or it is because of the dependence of the speed on the frequency and the number of pole pairs to increase the number of pole pairs accordingly. This leads however, because of the side by side arrangement provided on the machine scope from iron (poles) and copper (windings) to large machine diameters where for larger performances this trend because of the required effective cross further influence cuts.  

Reluctance machines of various types are also known (see DE- PS 197 43 380), which, however, only conditionally for low speeds and with under various additional expenses are suitable.

In Gottschalk, H., Lemberg, M. et al. (Ed.): "Elektrotechnik Elektronik", Berlin 1983 , 4 . Ed., Pp. 120 and 182-185, describes a medium-frequency generator of the Guy type, in which an unwound rotor is rotatably mounted in a medium-frequency winding (as a coil to be induced) stator. The shape of the rotor and stator on the circumference of the air gap causes large fluctuations in the magnetic flux in the coil to be induced during relative movement, which leads to voltage induction.

For this purpose, the stator has axially extending teeth on the air gap side. One in stator The excitation winding introduced into the slots determines excitation poles, which are caused by a pole gap in first and second sub-poles are divided. The pole gap takes the medium frequency wick lung on. Their width is chosen so that the teeth of the first partial pole to the Teeth of the respective second partial pole offset by a tooth width in the circumferential direction are.

The rotor has no windings. It carries evenly on its perimeter catch axially extending teeth, the tooth pitch of the stator teeth inside half of the partial poles which corresponds to the rotor toothing.

When the rotor rotates, the end faces on the air gap stand alternately the teeth of the rotor and the first or second partial pole opposite each other, so that the maximum of the magnetic flux changes between the two partial poles rare. The corresponding changes in direction cause a voltage induction in the medium frequency winding.

Known machines described above, however, lead in design for larger outputs inevitably lead to large machine diameters, because larger outputs to be implemented corresponding cross sections of iron and Copper conditionally arranged side by side primarily on the machine circumference are.  

From Weh, H .: "Permanent magnet excited synchronous machines of high force density according to the transverse flux concept", etzArchiv 10 ( 1988 ) 5, pp. 143-149, it is also known to design permanent magnet excited synchronous machines in such a way that the useful flow in the plane is transverse to the direction of movement ( ie transversal), so that the effective iron and copper cross-sections no longer have to be arranged next to one another on the circumference of the machine. The concept shown makes it possible to achieve high power densities and low winding losses, which means low power ratings and compact designs.

From DE-PS 44 00 443 is also a transverse flux machine with a cylindrical rotor known, which is designed for high speeds.

However, these known machine designs are not ge as slow-moving is suitable. The permanent magnet excited design also prevents simple che controllability in the power output during generator operation and limited in total including the performance of the machines. A three-phase version requires a triple arrangement of corresponding sub-machines on a shaft.

In view of the disadvantages of this known prior art, the inventor based on the task of creating a heteropolar excited reluctance machine gangs mentioned to create the use in relatively low speed range chen especially with larger performances and with reasonable machine diameters knives guaranteed.

This object is achieved according to the invention by a transverse arrangement of a A plurality of magnetic Er provided in the circumferential direction of the stator / rotor excitation circles, each over the air gap between a tooth of the stator tion and a tooth of the rotor teeth are closable.

Through this transfer of the transverse flow principle to Reluk dance machines of the type mentioned at the beginning there is the possibility of conception and execution of relatively slow running machines for greater performances reasonable machine diameters. In particular, reluctance can now also machines a side by side arrangement provided on the machine scope  effective iron and copper cross-sections (apart from the winding heads) are avoided, so that inexpensive and compact designs can be realized. Lei Influences on the machine diameter due to performance can be considerably reduced be changed.

The transverse arrangement of a plurality of arranged on the machine circumference Magnetic circuits leads to the fact that the useful magnetic flux in the plane transverse to the loading direction of movement of the rotor, d. H. the effective iron and copper cross cuts can advantageously be used in reluctance machines contrary to the usual Design to be arranged parallel to the machine axis. With that are on advantageous and expedient way the inherent advantages of reluctance machines can be combined with those of transverse flux machines, their Disadvantages (especially with regard to low speed, easy controllability, lei equipment, multi-phase structure) can be avoided.

In an advantageous embodiment of the invention, the stator does not consist of magnetically conductive material, in the magnetically conductive, essentially axially and First magnetic circuit parts extending transversely to the circumferential direction are attached by whose end faces on the air gap side form the teeth of the stator toothing.

The first magnetic circuit parts are expediently E-shaped, the three of which Leg ends facing the air gap, with the expedient the Erre ger- and the phase windings introduced in the first magnetic circuit parts Grooves (the openings forming the legs of the first magnetic circuit parts) are arranged.

The first magnetic circuit parts exist to reduce eddy current losses from individual, mutually insulated sheet iron layers, the contact plane NEN of the iron sheets lie in planes that of the radius vector and the rotor axis are spanned.

This practical and inexpensive design of the stator allows one on the stand side transverse guidance of the magnetic flux with simple and inexpensive Manufacturability.  

Expediently continue to form a defined number in the circumferential direction in defi nier tooth pitch on the stator arranged first magnetic circuit parts a first part pole of an excitation pole and an equal number of circumferentially in the same Tooth pitch on the stator arranged magnetic circuit parts a second partial pole of the same excitation poles, which are interrupted by a pole gap, and which Subpoles of other excitation poles with a corresponding number of first magnetic circuit parts and Connect the appropriate tooth pitch.

The two sub-poles of an excitation pole are of an excitation winding comprises that the first magnetic circuit parts assigned to the corresponding partial poles are penetrated by an excitation winding.

In a further expedient embodiment, the phase windings each comprise two sub-poles of adjacent different excitation poles such that the ent first magnetic circuit parts of a phase associated with the partial poles winding are interspersed. Furthermore, they are covered by a phase winding Subpoles of neighboring different excitation poles by a subpole gap in this way separated that the first magnet assigned to the corresponding partial poles Circular parts in the circumferential direction in the air gap plane have the partial pole gap.

For the purpose of multi-phase construction in one unit, the phase windings rotate current and accordingly at least one phase coil is provided per phase. There in a particularly advantageous embodiment, each phase coil contains at least two pole windings, each pole winding two subpoles different neighbors bear excitation poles. The individual poles are in the circumferential direction of the stator windings arranged alternately per phase, the pole windings of each phase sensor coil can be connected in series or in parallel.

For the purpose of accommodating the winding heads of the excitation and phase windings If the functional principle of the machine is safeguarded, the pole gap is one integer multiple plus one determined by the number of phases Fraction of the tooth pitch of the stator toothing and the partial pole gap an integer Multiples of the tooth pitch of the stator toothing.  

In a further expedient embodiment of the invention, the rotor consists of ma gnetically non-conductive material, in the magnetically conductive, essentially axially extending second magnetic circuit parts are attached, through the air gap side End faces the teeth of the rotor teeth are formed. The are advantageous second magnetic circuit parts designed yoke-shaped, but other designs are also realizable.

The second magnetic circuit also exists to reduce eddy current losses parts from individual, mutually insulated sheet iron layers, the touch planes of the iron sheets lie in levels that are defined by the radius vector and the Ro door axis are clamped.

This expedient design of the rotor allows it to be simple and cost-effective favorable producibility, the stator being guided transversely on the magnetic side Circle can be closed in the implementation of the reluctance principle. Electrical power need not be transferred to the rotor; corresponding failure-prone Components such as slip ring transformers, commutators etc. are avoided. Still is the machine can be controlled directly (via the excitation current).

To improve the time course of the chip generated by the generator The contours of the air gap are the key to reducing the cogging torque end faces of the teeth of the rotor and stator teeth so designed that the induced phase voltages in the associated phase windings Preserve sinusoid.

The air gap has a conveniently designed and manufacturable approximation solution end faces of the teeth of the stator toothing on a flat surface, weh rend the air gap-side end faces of the teeth of the rotor teeth of the outer surface follow the rotor.

The reluctance machine according to the invention is advantageously a generator or can be operated as a motor.  

Depending on the specific application, direct current is pulsed to the excitation winding Direct current or alternating current can be applied.

The machine according to the invention is designed as an internal or external rotor type bar. It is also available with a rotary or translatory input / output (e.g. as a linear motor) realizable.

The invention is explained in more detail below using an exemplary embodiment. In the associated drawings show:

Fig. 1 is a partially schematic and fragmentary view of the axial section along the line II in Fig. 2 ne by an inventive Reluktanzmaschi,

FIG. 2 shows a detail of the section along the line II-II in FIG. 1

Fig. 3 is a simplified and partial representation of the view of the inside of the stator from the air gap (rolled out on a different scale and in the plane).

According to the exemplary embodiment, a DC-excited three-phase generator is used in Inner rotor design described and shown.

The machine consists of an essentially hollow cylindrical stator 1 made of magnetically and electrically non-conductive material, in which a roller-shaped rotor 3 fastened to a shaft 2 is rotatably mounted ( FIGS. 1 and 2). A plurality of first magnetic circuit parts 4 are fastened on the circumference inside the stator 1 . These consist of magnetically good conductive material. In the example, it is a question of individual, mutually insulated sheet iron layers, the contact planes of which lie in planes (approximately) spanned by the radius vector and the axis of the rotor 3 .

The first magnetic circuit parts 4 expediently have the shape of an E in the axial section plane ( FIG. 1), the three leg ends of which face the air gap 5 of the machine. That is, the longitudinal extent of the first magnetic circuit parts 4 runs parallel to the axis of the rotor 3 . In the E-shape of the first magnetic circuit parts 4 bil denden grooves 6 (or corresponding openings), the excitation windings 7 and the phase windings 8 are housed, as will be explained in more detail below.

The rotor 3 is also made of magnetically and electrically non-conductive material. On its outer circumference, magnetically highly conductive second magnetic circular parts 9 are fastened in such a way that they are embedded in grooves in the rotor 3 . These second magnetic circuit parts 9 are yoke-shaped; they serve to draw conclusions (via the air gap 5 ) of the magnetic excitation circuits excited in the first magnetic circuit parts 4 . For the sake of reducing eddy current losses, they also consist of mutually insulated sheet iron layers, the contact planes of which lie in planes that are (approximately) spanned by the radius vector and the axis of the rotor 3 .

The second magnetic circuit parts 9 and their arrangement on the circumference of the rotor 3 form a (magnetically active) rotor toothing 3.1 with a pitch that is constant over the rotor circumference. That is, the end faces of the yoke-shaped second magnetic circuit parts 9 on the air gap side are intended to represent teeth, while the respective tooth gaps are formed by the spaces between magnetically non-conductive material between two teeth (see FIG. 2). The thickness of the second magnetic circuit parts 9 preference, equal to or smaller than the tooth width in the stator 1 and the arrangement is so ge that the size of the tooth width corresponds at most to the size of the tooth gap. Accordingly, the size of the tooth pitch is twice the stator-side tooth width.

This rotor toothing 3.1 is assigned a stator toothing 1.1 as follows:
The teeth of (magnetically active) 1.1 Statorzahnung are formed by the periphery-side arrangement of the first magnetic circuit parts 4 inside the stator 1, wherein the air-gap-side end faces of the first magnetic circuit part 4 to make the teeth are. Their tooth width corresponds to the thickness of the first magnetic circuit parts 4 , which is equal to the thickness of the second magnetic circuit parts 9 . The size of the respective tooth gaps is defined as follows:
The excitation windings 7 determine on the inner circumference of the stator 1 from alternating north and south magnetic excitation poles (see also FIG. 3). Each of these excitation poles (not shown) is subdivided into a first and a second part pole, each with a pole gap 10 in between. According to the exemplary embodiment, a first partial pole is formed by the three first magnetic circuit parts 4.1 and a second partial pole by the three first magnetic circuit parts 4.2 . The size of the tooth gaps within the respective partial poles corresponds to the (constant) tooth width, ie the teeth have constant tooth pitch. The size of the pole gap 10 is an integral multiple of the pitch of the rotor toothing 3.1 or the stator toothing 1.1 plus a fraction of the tooth pitch determined by the number of phases. In the example, the pole gap 10 defined as the distance between the last tooth of the first partial pole and the first tooth of the second partial pole is equal to 2 2/3 of the tooth pitch, in order to ensure the required space for the winding heads of the phase winding 8 while ensuring the function.

The phase windings 8 are arranged on the inner circumference of the stator 1 such that they each comprise two sub-poles of adjacent different excitation poles (see FIG. 3). Between these partial poles and accordingly between the different excitation poles, partial pole gaps 11 are arranged, which may be made smaller due to the lower space requirement of the winding heads of the excitation windings 7 . The size of the partial pole gap 11 (distance between the last tooth of the second partial pole and the first tooth of the following partial pole of the next excitation pole) is an integer multiple of the tooth pitch, in the example a tooth pitch, so that the tooth tip of the stator 1 to the tooth tip of the rotor 3 in one position of a second partial pole, the teeth of the following partial pole (assigned to the next excitation pole) face the tooth gaps of the rotor 3 .

The phase windings 8 consist of three phase coils each assigned to the phases, each phase coil expediently containing two pole windings 8.1 , each of which comprises two sub-poles of different adjacent excitation poles. The individual pole windings 8.1 are arranged alternately per phase in the circumferential direction of the stator 1 . They can be connected in series or in parallel as required.

The dimensioning of the machine according to the example, in particular the number of poles, the size of the pole gaps 10 and the partial pole gaps 11 , the number of teeth of the rotor toothing 3.1 and the stator toothing 1.1 , depends on the desired properties of the machine, such as, for. B. the number of phases and the frequency of the alternating current generated at a given speed.

For reasons already explained, the contours of the end faces of the teeth of the rotor teeth 3.1 and the stator teeth 1.1 on the air gap side are to be designed in such a way that the phase voltages induced in the assigned phase windings 8 receive a sinusoidal curve that is as accurate as possible. In accordance with the approximate solution, for example, the end faces of the teeth of the stator toothing 1.1 on the air gap side have a flat surface (see FIG. 2). The air-gap end faces of the teeth of the rotor teeth 3.1 , on the other hand, are adapted to the cylindrical outer surface of the rotor 3 .

The mode of action is as follows:
When the excitation windings 7 are charged with direct current, a (for the time being) ho mogenic magnetic field in the excitation circuits formed by the first magnetic circuit parts 4 and the second magnetic circuit parts 9 , at least one partial pole, in which the tooth heads of the rotor toothing 3.1 and stator toothing 1.1 - are separated by the air gap 5 - face. In this position, the magnetic resistance effective per magnetic circuit is the lowest, ie the magnetic flux reaches its maximum. In contrast, the tooth heads of the stator toothing 1.1 are located only partially or not in the neighboring partial poles of the tooth heads of the rotor toothing 3.1 , ie the magnetic resistance is considerably greater.

When the rotor 2 rotates, the tooth heads of the stator toothing 1.1 and the rotor toothing 3.1 , which are opposite each other, take place periodically, ie there is a corresponding periodic change in the magnetic flux, which leads to the induction of a voltage in the phase windings 8 .

Due to the inventive arrangement and design of the first magnetic circuit parts 4 and the second magnetic circuit parts 9 in a particularly axially effective direction, the useful flow is transversal, that is, transverse to the direction of movement with all the advantages explained.

The invention is not by the details of the above embodiment limited. In particular, the machine can be a generator or a motor leads. Depending on the application, the field winding can also be pulsed most direct current or alternating current. In addition to the explained Internal rotor - the external rotor design can be implemented in the same way. Likewise, the Ma can be designed as a linear machine.

Claims (23)

1. Heteropolarly excited reluctance machine, consisting of a stator provided with axially extending teeth on the air gap side, which carries excitation and phase windings, the excitation winding defining excitation poles of the stator, which are subdivided in the circumferential direction into a first and a second partial pole with a pole gap located between them and the pole gap causes a circumferential offset of the teeth of the respective second to the first partial pole, and consists of a winding-less rotor which is provided with axially extending teeth in the circumferential direction on the air gap side, the tooth pitch of the stator toothing within the partial poles corresponding to that of the rotor toothing, characterized by a transverse arrangement of a plurality of magnetic exciters provided in the circumferential direction of the stator ( 1 ) / rotor ( 3 ), each of which via the air gap ( 5 ) between a tooth of the stator toothing ( 1.1 ) and a tooth of the rotor tooth clue ( 3.1 ) can be closed. 2. Heteropolar excited reluctance machine according to claim 1, characterized in that the stator ( 1 ) consists of magnetically non-conductive material, in the magnetically conductive, extending substantially axially and transversely to the circumferential direction extending first magnetic circuit parts ( 4 ) by whose end faces on the air gap side form the teeth of the stator toothing ( 1.1 ). 3. Heteropolar excited reluctance machine according to claim 1 and 2, characterized in that the first magnetic circuit parts ( 4 ) are designed E-shaped, de ren three leg ends facing the air gap ( 5 ). 4. Heteropolar excited reluctance machine according to claim 1 to 3, characterized in that the exciter ( 7 ) and the phase windings ( 8 ) in which he most magnetic circuit parts ( 4 ) introduced grooves ( 6 ) are arranged. 5. heteropolar excited reluctance machine according to claim 1 to 4, characterized in that the first magnetic circuit parts ( 4 ) consist of individual, against each other the isolated sheet iron layers, the contact planes of the egg senbleche lie in planes that are spanned by the radius vector and the rotor axis . 6. heteropolar excited reluctance machine according to claim 1 and one or more of claims 2 to 5, characterized in that a defined number of circumferentially in a defined tooth pitch on the stator angeord Neter first magnetic circuit parts ( 4 ) a first partial pole of an excitation pole and an equal number of In the circumferential direction in the same tooth pitch on the stator, first magnetic circuit parts ( 4 ) form a second partial pole of the same excitation pole, which are interrupted by a pole gap ( 10 ), and the partial poles of other excitation poles with a corresponding number of first magnetic circuit parts ( 4 ) and corresponding tooth pitch connect. 7. heteropolar excited reluctance machine according to claim 1 and 6, characterized in that the two sub-poles of an excitation pole of an excitation winding ( 7 ) are included in such a way that the corresponding partial poles assigned to the first magnetic circuit parts ( 4 ) of an excitation winding ( 7 ) are enforced. 8. Heteropolar excited reluctance machine according to claim 1 and one or more of claims 2 to 7, characterized in that the phase windings ( 8 ) each comprise two sub-poles of adjacent different excitation poles such that the first magnetic circuit parts ( 4 ) assigned to the corresponding partial poles a phase winding ( 8 ) are interspersed. 9. Heteropolar excited reluctance machine according to claim 1 and 8, characterized in that the partial poles comprised by a phase winding ( 8 ) are adjacent different excitation poles separated by a partial pole gap ( 11 ) such that the first magnetic circuit parts ( 4 ) assigned to the corresponding partial poles have the partial pole gap ( 11 ) in the circumferential direction in the air gap plane. 10. Heteropolar excited reluctance machine according to claim 1 and one or more of claims 2 to 9, characterized in that the phase windings ( 8 ) carry three-phase current and accordingly at least one phase coil is provided per phase. 11. Heteropolar excited reluctance machine according to claim 10, characterized in that each phase coil contains at least two pole windings ( 8.1 ), each pole winding ( 8.1 ) comprising two sub-poles of different adjacent He excitation poles. 12. Heteropolar excited reluctance machine according to claim 11, characterized in that the individual pole windings ( 8.1 ) are arranged alternately per phase in the circumferential direction of the stator ( 1 ). 13. Heteropolar excited reluctance machine according to claim 11, characterized in that the pole windings ( 8.1 ) of each phase coil can be switched in series or parallel. 14. Heteropolar excited reluctance machine according to claim 10, characterized in that the pole gap ( 10 ) is an integer multiple plus a fraction determined by the number of phases of the tooth pitch of the stator toothing ( 1.1 ) and the partial pole gap ( 11 ) is an integer multiple of the tooth pitch of the stator toothing ( 1.1 ) is. 15. Heteropolar excited reluctance machine according to claim 1, characterized in that the rotor ( 3 ) consists of magnetically non-conductive material in which magnetically conductive, substantially axially extending second magnetic circuit parts ( 9 ) are attached, through the air gap-side end faces the teeth the rotor teeth ( 3.1 ) are formed. 16. Heteropolar excited reluctance machine according to claim 15, characterized in that the second magnetic circuit parts ( 9 ) are yoke-shaped. 17. Heteropolar excited reluctance machine according to claim 15 and 16, characterized in that the second magnetic circuit parts ( 9 ) consist of individual, mutually insulated sheet iron layers, the planes of contact of the iron sheets lying in planes spanned by the radius vector and the rotor axis. 18. Heteropolar excited reluctance machine according to claim 1, 2 and 15, characterized in that the contours of the air gap-side end faces of the teeth of the rotor ( 3.1 ) and the stator toothing ( 1.1 ) are designed such that the induced in the associated phase windings ( 8 ) Get phase voltages a Si nusform. 19. Heteropolar excited reluctance machine according to claim 18, characterized in that the air gap-side end faces of the teeth of the stator toothing ( 1.1 ) have a flat surface as an approximate solution, while the air gap-side end faces of the teeth of the rotor toothing ( 3.1 ) of the lateral surface of the rotor ( 3 ) consequences. 20. Heteropolar excited reluctance machine according to claim 1, characterized in that it can be operated as a generator or as a motor. 21. Heteropolar excited reluctance machine according to claim 1 and one or more of the following claims, characterized in that on the excitation winding ( 7 ) direct current, pulsed direct current or alternating current can be placed on it. 22. Heteropolar excited reluctance machine according to claim 1, characterized records that the machine can be executed as an internal or external rotor type. 23. Heteropolar excited reluctance machine according to claim 1 and one or more of the following claims, characterized in that the rotor ( 3 ) relative to the stator ( 1 ) a rotational or a translational Be movement can be carried out.