DE102013207806A1 - Electric machine - Google Patents

Abstract

The invention relates to an electrical machine with a rotor (2, 3) and a stator (1) with a plurality of stator poles, a stationary can (9) being arranged between the rotor and the stator. According to the invention, the can (9) has alternating magnetic segments (91) and non-magnetic segments (92), the magnetic segments (91) being arranged below the stator poles and the non-magnetic segments (92) being arranged between the stator poles. Such an electrical machine has a higher degree of efficiency with a lower current flow at the same time.

Description

The invention relates to an electrical machine.

Such an electric machine comprises a rotor and a stator, wherein a gap tube is arranged between the rotor and the stator.

In the known cases, the electric machines are used, for example, as drive motors in industrial applications, in electric vehicles (railway vehicles, electric cars) or in rotary anode X-ray tubes.

In electric machines of all kinds, the air gap between stator and rotor is usually dimensioned as small as possible in order to maximize the magnetic effect of the stator on the rotor. In a drive motor for a rotary anode X-ray tube, however, a relatively large air gap must be accepted, since the rotor is located together with the rotary anode within the vacuum envelope, but the stator is disposed outside of the vacuum envelope.

X-ray sources with a rotary anode drive are in each case for example from the DE 10 2006 058 234 A1 and from the DE 10 2011 077 746 A1 as well as from the DE 10 2011 007 114 B3 and the DE 10 2011 081 280 A1 known.

When used as a rotary anode drive, the can, which is present between the stator and the rotor in all electrical machines of the type mentioned at the beginning, must be vacuum-compatible (vacuum-tight), ie. The material from which the can is made, must have no cracks and no voids.

Depending on the technologies used in X-ray tubes, this can is made of glass, ceramic or metal.

In the case of a split tube made of glass and ceramic, a large wall thickness is required for mechanical reasons, so that a large magnetically active air gap results. Due to the large air gap, a high magnetizing current in the stator is necessary in order to achieve the necessary field strength for the required torque despite the large air gap. This leads to large ohmic losses in the stator and thus to a reduction in the efficiency of the electric machine.

A metallic canned can be made much thinner. But then the eddy current losses in this can, which also lead to a reduction of the efficiency of the electric machine, are problematic.

If the rotor is at high voltage potential, an even greater distance must be maintained in order to ensure a corresponding electrical insulation. A rotary anode drive therefore has a relatively low power density in principle compared to a standard drive. In addition, the space provided for the stator is often limited, so that the stator can not be easily increased.

In the case of bipolar X-ray sources (anode is, for example, +75 kV, cathode is, for example, -75 kV), the stator, which is grounded, must be insulated from the rotor, which is at anode potential, for the applied high voltage, so that the insulation distance required for this purpose essentially determines the air gap.

In the case of the unipolar X-ray emitters preferred for their good coolability (anode is at 0 V, cathode is at -150 kV, for example), the electric drive system is determined by the geometry of the can.

Currently, the low efficiency of anode drive systems for X-ray sources is accepted. For cost reasons, a metal can is often used in ball-bearing tubes, since the high torques are needed only within the acceleration time. In the case of sliding bearing emitters, ceramic splitting tubes make sense, despite the higher costs, because otherwise the high level of continuous torques can not be used to cool the split tube adequately.

The object of the present invention is to provide an electrical machine which has a higher efficiency with simultaneously lower current flow.

The object is achieved by an electric machine according to claim 1. Advantageous embodiments of the electric machine according to the invention are the subject of further claims.

The electric machine according to claim 1 comprises a rotor and a stator having a plurality of stator poles, wherein a stationary can is arranged between the rotor and the stator. According to the invention, the can has alternating magnetic segments and non-magnetic segments, wherein the magnetic segments are arranged below the stator poles and the non-magnetic segments between the stator poles.

The magnetic segments have, for example, a relative (vacuum-related) permeability of μ _r > 100, preferably 200 <μ _r <1,000.

In the electric machine according to claim 1 is reduced by the use of a split tube, which alternately consists of magnetically conductive and magnetically non-conductive segments, the magnetically effective air gap to the gap thickness. As a result, the electric machine according to claim 1 has a significantly improved efficiency and the required current flow decreases accordingly.

Due to its advantages, the solution according to the invention is particularly suitable as an electric drive motor for a rotary anode X-ray tube. According to a preferred embodiment according to claim 2, the segmented can thus forms the vacuum envelope of the rotary anode X-ray tube. This results in a rotary anode X-ray tube according to claim 7 and a rotary anode X-ray source according to claim 8, each having a correspondingly compact construction.

According to an advantageous embodiment according to claim 3, the can is made of metal. In this embodiment, the alternating segments are made of a high permeability metal (e.g. magnetic stainless steel) and a low permeability metal (e.g. non-magnetic stainless steel). In vacuum applications, such as an anode drive in a rotary anode X-ray tube, care should be taken that the segments are assembled without gaps to ensure the required vacuum capability.

As an alternative to an embodiment according to claim 3, the can also consist of a plastic in which metal particles with different permeability are embedded.

The solution according to the invention can be realized in a variety of different electrical machines in an advantageous manner. According to claim 4, the electric machine is designed for example as an asynchronous motor. An embodiment as a synchronous motor, as described in claim 5, is easily implemented. According to a further preferred embodiment according to claim 6, the electric machine is designed as a synchronous motor.

If the rotor is designed as a squirrel-cage rotor in an asynchronous machine, or if a reluctance machine is used as the air gap, only the mechanically necessary distance between the rotating rotor and the stationary can remains.

Although the segmented can provided according to the invention can not reduce the eddy current losses in the can, due to the pole extension of the stator, the stator current is reduced. This also reduces the ohmic losses in the stator, which increases the motor efficiency accordingly. In addition, the frequency converter required for controlling the electrical machine only has to be designed for smaller currents.

The solution according to the invention, the space required for the electric drive space can be significantly reduced, so that either - with constant effect - the electric drive can be designed more compact, or - with the same size - the moment generated by the electric drive can be increased.

Hereinafter, two schematically illustrated embodiments of the invention will be explained with reference to the drawing, but without being limited thereto. Show it:

1 a cross section through a first embodiment of an electrical machine,

2 a cross-section through a second embodiment of an electric machine, and

3 a perspective view of a can for an electric machine according to 1 ,

In the 1 and 2 illustrated electric machines each comprise a stator formed as a laminated stator 1 who has a rotor 2 ( 1 ) or a rotor 3 ( 2 ) completely encloses in the circumferential direction.

The stator 1 has on its inner circumference a predetermined number of radially inwardly facing stator teeth 4 on. At the in 1 and in 2 shown electric machines there are six stator teeth 4 , However, it is also a different number of stator teeth 4 possible.

Between two adjacent stator teeth 4 is each a groove 5 in stator laminated core 1 arranged. In every groove 5 is each a stator winding 6 inserted, which is designed as yoke winding, for example.

A predefinable number of stator teeth 4 each forms a stator pole. In the exemplary embodiments illustrated, each stator tooth forms 4 one stator pole each.

The rotor 2 ( 1 ) comprises a rotor winding 7 whereas the rotor 3 ( 2 ) radially outwardly directed rotor teeth 8th has and off a soft magnetic material. In the illustrated embodiment, the rotor has 3 five rotor teeth 8th , In principle, the rotor 3 also a different number of rotor teeth 8th exhibit. It should only be noted that the number of stator teeth 4 and the number of rotor teeth 5 must be different.

At the in 1 The electric machine shown is thus an asynchronous machine which is designed as a cage rotor. In contrast, the in 2 represented electrical machine to a reluctance machine that can be operated synchronously or switched.

Between the rotor 2 ( 1 ) or the rotor 3 ( 2 ) and the stator 1 is in each case a stationary can 9 arranged. According to the invention, the split tube 9 alternating magnetic segments 91 and non-magnetic segments 92 on.

The magnetic segments 91 are under the stator poles (in the illustrated embodiments, these are the stator teeth 4 ) arranged. The non-magnetic segments 92 are between the stator poles (in the illustrated embodiments, these are the slots 5 ) arranged.

By the solution according to the invention, between the stator 1 and the rotor 2 , a canned pipe 9 to arrange, alternately of magnetically conductive segments 91 and of magnetically non-conductive segments 92 exists, the magnetically active air gap is reduced by the gap thickness. As a result, such an electric machine has a significantly improved efficiency and the required current flow decreases accordingly.

In 3 an embodiment of a split tube 9 shown. The can 9 is for the in 1 illustrated asynchronous machine suitable. The magnetic segments 91 and the non-magnetic segments 92 Each has a rectangular shape and run alternately and parallel to each other, wherein the magnetic segments 91 and the non-magnetic segments 92 have the same axial length, which is shorter than the axial length of the can 9 ,

At the in 1 (Asynchronous machine with squirrel cage) and in 2 (Reluctance machine) illustrated embodiments remains as an air gap only the mechanically necessary distance between the rotating rotor 2 respectively. 3 and the standing can 9 ,

By provided according to the invention segmented can 9 are the eddy current losses in the can 9 not reduced. Because of the magnetic segments 91 but the stator teeth 4 and thus the poles of the stator 1 be extended, however, the stator current decreases. This will also be the ohmic losses in the stator 1 lower, whereby the motor efficiency increases accordingly.

The solution according to the invention, the space required for the electric drive space can be significantly reduced, so that either - with constant effect - the electric drive can be designed more compact, or - with the same size - the moment generated by the electric drive can be increased.

The invention is applicable to a variety of electrical machines, e.g. in asynchronous machines (with squirrel cage or bell runner) and in reluctance machines (synchronous or switched) feasible.

As can be seen from the description of the embodiments shown in the drawing, the solution according to the invention reduces the magnetically active air gap and reduces the stator current at the same torque. Furthermore, the proposed solution in an electric machine increases the motor efficiency or reduces the installation space for the stator. Compared to an electrical machine according to the prior art, a more compact construction is achieved by the inventive solution.

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

• DE 102006058234 A1 [0005]
• DE 102011077746 A1 [0005]
• DE 102011007114 B3 [0005]
• DE 102011081280 A1 [0005]

Claims (8)

Electric machine with a rotor ( 2 . 3 ) and a stator ( 1 ) with a plurality of stator poles, wherein between the rotor ( 2 . 3 ) and the stator ( 1 ) a stationary can ( 9 ), characterized in that the can ( 9 ) alternately magnetic segments ( 91 ) and non-magnetic segments ( 92 ), wherein the magnetic segments ( 91 ) under the stator poles and the non-magnetic segments ( 92 ) are arranged between the stator poles. Electrical machine according to claim 1, characterized in that the can ( 9 ) forms a vacuum envelope of a rotary anode X-ray tube. Electrical machine according to claim 1, characterized in that the can ( 9 ) consists of metal. Electrical machine according to claim 1, characterized in that it is an asynchronous motor. Electrical machine according to claim 1, characterized in that it is a synchronous motor. Electrical machine according to claim 1, characterized in that it is a reluctance motor. X-ray tube with a vacuum envelope, in which a rotary anode is mounted, characterized in that the vacuum envelope is a split tube ( 9 ) forms an electric motor through which the rotary anode is driven. X-ray source comprising a radiator housing, in which a rotary anode X-ray tube is arranged, which comprises a vacuum envelope, characterized in that the vacuum envelope is a split tube ( 9 ) forms an electric motor through which the rotary anode is driven.

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