EP3403316A1

EP3403316A1 - Rotor of a permanent-magnet dynamoelectric rotary machine, and use of said machine

Info

Publication number: EP3403316A1
Application number: EP17703062.4A
Authority: EP
Inventors: Bernd Pfannschmidt; Tobias Stärz; Wolfgang Wetzel
Original assignee: Siemens AG
Current assignee: Siemens AG
Priority date: 2016-02-22
Filing date: 2017-01-26
Publication date: 2018-11-21
Also published as: RU2698323C1; EP3208913A1; CN108702046A; WO2017144228A1; US20210194303A1

Abstract

The invention relates to a rotor (4) of a permanent-magnet dynamoelectric rotary machine (1), comprising a pot-type support unit (5) that has at least one cylindrical wall; permanent magnets (8) are arranged on the outer periphery of the wall of said support unit (5), and substantially axially extending cooling ducts (7) are provided within the wall.

Description

description

Rotor of a permanent magnet dynamoelectric

rotary machine and its use

The invention relates to a rotor of a permanent magnet dynamoelectric rotary machine, a dynamoelectric rotary machine and a use of such a machine.

For permanent-magnet dynamo-electric machines, the magnetic material of the permanent magnets depending on the alloy together ^¬ mensetzung to a maximum permissible upper limit of the Einsatztem ^¬ temperature. If this is exceeded, there occurs a wrong ^¬ versible demagnetization of the magnetic material, which can destroy the rotor or at least significantly adversely affect the performance of the dynamoelectric machine. An impermissible heating of the permanent magnets of the rotor during operation of a dynamoelectric machine by eddy current losses and heat input through the air gap from the stator can be prevented by a targeted air cooling of the rotor.

So far, such rotary dynamoelectric machines are provided with radial or axial fans, which cause an exchange of air within the dynamoelectric machine, in particular via the air gap and thus bring about cooling of the permanent magnets, cooling the permanent magnets via the air gap of the permanent magnet However, dynamoelectric rotary machine is insufficient in many cases.

Assuming the invention has for its object to provide egg ^¬ NEN rotor of a dynamo-electric rotary machine which permits efficient cooling of its permanent magnets, has a comparatively low moment of inertia on ^¬ and is inexpensive to manufacture, to a wide variety thus a power ^¬ capable electric drive for To provide applications. The solution of the problem is achieved by a rotor of a permanent-magnet dynamoelectric rotary machine with a cup-like, at least one cylindrical wall having support unit, wherein permanent magnets are arranged on the outer circumference of the wall of this support unit and in the wall substantially axially extending Kühlka ^¬ channels are provided.

The solution of the problem is also achieved by ei ^¬ ne dynamoelectric machine with a rotor according to one of the preceding claims, wherein a stationary arranged Vorleitrad is connected upstream of the rotor.

Likewise, the solution of the problem by a machine tool, an electric car, a traction drive or an electrically powered aircraft, with at least ei ^¬ ner succeeds dynamoelectric machine.

The inventive cooling concept of the rotor, is now realized via a plurality of axially arranged cooling air ducts on a support unit. Due to the spatial proximity of the through-flow of cooling air channels to the permanent magnets sufficient cooling of the permanent magnets is guaranteed ^¬ makes. Due to the comparatively large surface of the cooling ^¬ channels, in particular by their number or additional axi ^¬ al extending ribs in the cooling channels now the losses of the permanent magnets of the rotor on the Tragein ^{¬ unit} convectively transmitted to the conveyed air and abge ^¬ leads.

These losses in the permanent magnets arise among other things by eddy currents.

The cooling channels are viewed in the circumferential direction ge ^¬ closed or open executed. Due to the open design of the cooling channels resulting in the direction of permanent magnets axi ^¬ al extending slots, which there is an immediate contact a cooling air flow at least to produce a part of a respective permanent magnet.

It is particularly advantageous if the support unit is made of a good thermal conductivity material, such as. made of aluminum.

To re ^¬ ducieren the weight and thus also the inertia of the rotor, this is in addition to a comparatively lightweight material, provided with a spoke-like support structure which is rotatably connected to the shaft. Therefore, this support structure is preferably provided only at one end of the support structure.

In order to dissipate the cooling air and to cool the winding head on at least one side of the stator obliquely outwardly leading portions of these cooling channels are provided at an axial end ^{¬ range of} the support unit, which are located in a projection of the support unit. This projection is, viewed axially, at one end of the cylinder-shaped wall of the support unit. Furthermore, obliquely outwardly leading ^{sections of} the cooling channels cause a radial fan ^action , due to the angled cooling channels, which, among other things, can also serve to cool the winding head at least on one side of the machine.

The rotor according to the invention thus combines the functions of torque transmission, cooling air promotion and the heat dissipation from the permanent magnet arranged on it.

The rotor thus has in the axial and in the radial direction a very compact construction and can relatively easily manufactured inexpensively as a conventional rotary or a milled part of a non-magnetic but relatively good heat conducting material, for example aluminum ^¬ the. This is achieved in particular by the fact that according to the invention no undercuts occur in such embodiments of the support unit and thus of the rotor during production and the machining planes lie in radially arranged planes.

In order to reduce the weight and hence the inertia of the rotor on, the rotor is provided as open on one side ^¬ Rotorglo ^¬ blocks or the support unit as a cup-like structure.

Fluidically it is particularly advantageous if a preferred direction of rotation of the rotary machine is then in the intake region of the rotor a stationary stator is arranged on ^¬, the air during the mainly axial Anströ ^¬ mens toward rotor offset a predetermined forward twist. Thus, the entry losses are reduced in the cooling channels of the support unit of the rotor due to flow separation.

Arranged on the support unit magnetic poles are either formed by classical magnets, ie north or south pole point to the air gap or by magnets in which the flow in the rotor run through the magnets themselves, such as laterally magnetized magnets or magnets in Hal ^¬ bach -Arrangement. Especially with classic magnets, a flow-guiding layer must be additionally arranged between the support unit and the magnet.

A combination of a hitherto known rotor or magnetic carrier with axial cooling channels and a flow-optimized shaft-fixed connected fan (radial / axial, suction / pressing) as a separate component, for example. produced with rapid prototyping technologies, represents an alternative solution of the inventive idea.

The invention and further advantageous embodiments of the invention are shown in the schematically illustrated embodiments. Showing:

1 shows a longitudinal section of such a machine, 2 shows a perspective view of a carrying unit,

3 shows a partial longitudinal section of a runner,

4 shows a partial longitudinal section of the rotor with a Vorleitrad,

5 shows a detailed view of the surface of the rotor,

6 and 7 partial longitudinal sections of runners with under ^¬ different projections,

8 to 10 partial cross-sections of runners.

1 shows a longitudinal section of a motor which can be used as a drive, for example a rail vehicle, an aircraft (e-aircraft) or a machine tool, the drive having a dynamoelectric rotary machine 1 with a permanent magnet-excited rotor 4. The dynamo-electric machine 1 has a stator 2, which is not in nä forth ^¬ shown axially extending slots of the laminated core of the stator winding 2, a system is provided which forms on the end faces of the stator winding heads 2. 3

Spaced by an air gap 15 of the stator 2 of the dynamo-electric machine 1, a rotor 4 is arranged which has, on a surface of a support unit 5 of the rotor 4 permanent magnets ^¬. 8 On the outer circumference of the supporting unit like a pot performed 5, which is cylindrical ge ^¬ formed at least in sections and the air gap faces 15 are therefore the permanent magnets 8. The supporting unit 5 is connected via a supporting structure 6 having a shaft rotatably supported around an axis 9 is.

The supporting structure 6 forming part of the support unit 5. In the one-piece design of the supporting unit 5, this includes at least the support structure 6, the cooling channels 7 and the off ^¬ cantilever sixteenth

Radial below the permanent magnets 8 substantially axially extending channels 7 are provided, the at least one end of a curvature or projection 16 each have an outlet 12 and thus generate a radial ^¬ ventilating effect upon rotation of the rotor 4, the at least one winding head 3 of the stator 2 additionally cools or at least for an air turbulence in this area provides.

For each magnetic pole, at least one permanent magnet 8 is basically provided in the axial and / or circumferential direction. There are also graduations or

Slanting of the magnetic poles over the axial length of the rotor considered provided that this is necessary for operation of the dynamoelectric rotary machine without cogging torques.

2 shows in a perspective view an integrally designed carrying unit 5, in which the axially ver ^¬ running cooling channels 7 and the projection 16 with their off ^¬ outlets 12 can be seen at one axial end of the support unit 5. The supporting unit 5 thus has in the axial and in the radial direction a very compact construction and can comparatively easily ^¬ as a conventional rotary or a milled part of a non-magnetic but relatively good heat conducting material, for example aluminum advertising inexpensively manufactured to. This is achieved in particular by the fact that in a derar ^¬ term execution of the support unit 5 and thus of the rotor 4 during production no undercuts occur and the processing levels are in radially arranged planes. FIG. 3 shows, in a detailed representation, the rotor 4, which has the recesses 7 radially below its permanent magnets 8, which act as cooling channels 7. On the axially ande ^¬ ren side of the rotor 4, these cooling channels 7 each receive an outwardly directed curvature, which opens into an outlet 12.

The shape of the projection 16 is essentially defined by two angles, β. By specifying these angles, β, the noise development, the blow-out direction of the Lasses 12, the radial fan action and the suction effect of the support unit 5 and thus of the rotor 4 influenced.

In addition to the rotor 4 of FIG. 3, during operation of the dynamo-electric machine 1 with a preferred direction of rotation, the rotor 4 is axially preceded by a stationary stator 10 in the flow direction according to FIG. 4 which is intended to reduce the flow losses of the cooling air entering the support unit 5. This is particularly advantageous in a preferred direction of rotation of the dynamo-electric machine 1.

FIG. 5 shows, in a further embodiment, a permanent magnet 8, which is arranged on an intermediate layer, which is preferably made of a laminated material, in order to better guide the magnetic flux. It is then a kind of laminated core 11 which is positioned on the support unit 5, e.g. has shrunk. This embodiment is to be provided especially in the case of the classic magnets in which, depending on the arrangement, 5 north or south pole to the air gap 15 on the wall of the support unit.

6 and 7 show different embodiments of the Läu ^¬ fers 4 with respect to the formation of the projection 16 and the outlet 12th

The shape of the projection 16 is also given here essentially by two angles, ß. The noise, the blowout direction of the outlet 12, the centrifugal fan action and the suction effect of the supporting unit 5 and hence the rotor 4 is impressed ^¬ enced by presetting this angle ß.

FIG. 8 shows, in a partial cross-section of the rotor 4, two magnetic poles 14 separated by a pole gap 13, on the one hand a north pole (N) and on the adjacent pole a south pole (S) pointing to the air gap 15. Each to korres ^¬ pondierende polarity facing the wall of the support unit 5. In order to guide the magnetic flux of these permanent To ensure magnets 8, between the wall of the support unit 5 and the permanent magnet 8 to provide a magnetically conductive material, as long as the support unit 5 is formed of material with a lack of magnetic conductivity. It is then a kind of laminated core 11, which is positioned on the support unit 5, for example, is ^¬ shrinks. The Perma ^¬ nentmagnete 8 are then fused to that sheet stack. 11 For each magnetic pole 14, at least one permanent magnet 8 is provided in the axial and / or radial and / or circumferential direction.

FIG 9 and FIG 10 differ only by the shape of the cooling channels 7. In FIG 9, these are closed when viewed in the circumferential direction. In FIG 10, the latter in the direction of permanent magnet and the air gap 8 15 are at least partially open radi ^¬ al.

FIGS. 9 and 10 have partial magnets with different magnetization direction 18 per magnetic pole 14 in the circumferential direction. Thus, the course of the magnetic flux per pole 14 is "simulated".

Ideally, these permanent magnets 8 are laterally magnetized. A laminated core 11 for flux guidance to the Ausführun- gen of FIG 9 and FIG 10 is thus no longer absolutely not ^¬ agile.

The permanent magnets 8 are basically arranged on the surface of the support unit 5, that is, the wall facing the air gap 15. They are fixed and secured there by glue and / or bandages.

The cooling channels 7 are executed in their axial course to the outlet 12 with almost identical cross-section. In order to achieve an improved cooling effect, the cooling channels 7 are provided in their axial course with a cross-sectional widening, which of course can only be accompanied by a reduction of the web widths 17. Likewise is one Cross-sectional change over the axial course conceivable, for example, from round to angular, as shown for example in FIG.

Furthermore, the number of cooling channels 7 is assigned directly to a width of the pole 14. In a pole gap 13 according to an embodiment of FIG 8, then, there, the web width 17 can be increased.

Such a dynamoelectric machine 1 with an inventions ^{¬ to the} invention runner 4 is, inter alia, due to the low mass and thus the inertia of the support unit 5 and the Effizi ^¬ enz the cooling of the permanent magnets arranged there 8, especially in production machines, such as machine tools, electric drives used in vehicles such as electric cars, traction drives of mining trucks or rail vehicles and electrically powered flying machines.

Claims

claims

1. rotor (4) of a permanent-magnet dynamoelectric rotary machine (1) having a cup-shaped, at least one cylindrical wall having support unit (5), where ^¬ at the outer periphery of the wall of this support unit (5) permanent magnets (8) are arranged and in the wall in wesent ^¬ union axially extending cooling channels (7) are provided, where ^¬ in the cooling channels (7) of the support unit (5) viewed in the circumferential direction closed and / or radially outwardly open, wherein the cooling channels (7) at one axial end the support unit (5) in a projection (16) open, and so on rotation of the rotor (4) produce a radial fan action.

2. rotor (4) according to claim 1, characterized in that the support unit (5) has a Tragstruk ^¬ structure (6) which is rotatably connected to a shaft and which is designed spoke-shaped.

3. The rotor (4) according to claim 1 or 2, characterized in that the support structure (6) is located at an axial end of the support unit (5).

4. rotor (4) according to any one of the preceding claims, characterized in that the permanent magnet Perma ^¬ (8) are arranged according to a Halbach arrangement or that the permanent magnets (8) are designed as laterally magnetized permanent magnets (8).

5. Dynamoelectric machine (1) with a rotor (4) according to one of the preceding claims, wherein a stationary arranged Vorleitrad (10) is upstream of the rotor (4) fluidly.

6. Machine tool, electrically driven vehicle or electrically powered aircraft, with at least one dyna ^¬ moelektrischen machine (1) according to claim 5.