The present invention is generally related to permanent magnet (PM) electromotive machines, such as electric generators and/or electric motors and, more particularly to fault tolerant PM machines.
It is known that electromotive machines may utilize permanent magnets (PMs) as a primary mechanism to generate magnetic fields of high magnitudes for electrical induction. Unlike machines that involve electromagnets, which can be electrically controlled, e.g., selectively turned on and off, PMs remain on. That is, magnetic fields produced by the PM persist due to their inherent ferromagnetic properties. Consequently, should an electromotive machine having PMs experience a fault, it may not be possible to expediently stop the machine because of the persistent nature of the magnetic fields of the PMs causing the machine to continue operating. Such faults may be in the form of fault currents produced due to defects in the stator windings or mechanical faults arising from defective or worn-out mechanical components disposed within the machine. The inability to disable the PM during the above-mentioned or other related faults may damage the PM machine and/or devices coupled thereto.
In view of the foregoing considerations, various machine and/or control architectures have been proposed to develop fault-tolerant PM machines. One type of fault-tolerant PM machine that has gained wide acceptance in view of its relatively low-cost and operational versatility involves fractional slot pitch concentrated windings. This type of fault-tolerant PM machine offers substantial reliability but in operation the excited windings may generate a rich spectrum of space harmonics, including a number of asynchronous harmonics that do not contribute to form useful magnetomotive force (MMF) but can give raise to electromagnetic losses in various components of the machine, such as rotor magnets and magnetic steel structures. Measures have been proposed, such as the use of thin laminated magnetic steel with lower core loss and/or axially-segmented magnets, which may help to ameliorate rotor cooling requirements.
However, such measures are essentially approaches designed to just mitigate the symptoms but do little or nothing to overcome the fundamental issues. For example, such measures essentially accept to “live” with the asynchronous harmonics and just try to reduce their detrimental effects (e.g., electromagnetic losses) by “laminating” the magnets and the core. Thus, such measures are likely to sacrifice power efficiency and add incremental costs. In view of the foregoing considerations, it should be appreciated that there continues to be a need of further improvements in connection with fault tolerant PM machines.
In one aspect of the invention a rotor structure for a permanent magnet electromotive machine is provided. At least one back-core lamination is disposed around a plurality of permanent magnets. The back-core lamination comprises a plurality of high-reluctance regions arranged to attenuate asynchronous magnetic flux components while avoiding synchronous magnetic flux components. The asynchronous and synchronous magnetic flux components result from spatial harmonic components of a plurality of fractional-slot concentrated windings of a stator of the machine.
In another aspect of the invention an electromotive permanent magnet machine is provided. A stator includes a plurality of fractional-slot concentrated windings. A rotor is operatively coupled to the stator. The rotor has a plurality of stacked back-core laminations disposed around a plurality of permanent magnets. Each back-core lamination comprises a plurality of high-reluctance regions arranged to attenuate asynchronous magnetic flux components while avoiding synchronous magnetic flux components. The asynchronous and synchronous magnetic flux components result from spatial harmonic components of the windings of the stator of the machine.
In yet another aspect, a method to construct a rotor for a permanent magnet electromotive machine is provided. A back-core lamination is disposed around a plurality of permanent magnets in a rotor of the machine. A plurality of high-reluctance regions is defined in the back-core lamination. The plurality of high-reluctance regions may be located to maximize a reluctance in a path of asynchronous magnetic flux components while having a minimal effect on the synchronous components thereby maximizing a power density of the machine. The asynchronous and synchronous magnetic flux components result from spatial harmonic components of a plurality of fractional-slot concentrated windings of a stator of the machine.
These and other features, aspects, and advantages of the present invention will become better understood when the following detailed description is read with reference to the accompanying drawings in which like characters represent like parts throughout the drawings, wherein:
As discussed in greater detail below, aspects of the invention are directed to fault tolerant permanent magnet machines as may involve fractional slot pitch concentrated windings. As used herein, the term “fault tolerant” refers to magnetic and physical decoupling between various machine coils/phases while reducing noise, torque ripple, and harmonic flux components.
The inventors of the present invention propose an innovative and elegant approach suitable for substantially reducing electromagnetic rotor losses generally associated with a spectrum of space harmonics of the fractional slot pitch concentrated windings. As previously noted, such spectrum includes a number of asynchronous harmonics that do not contribute to useful MMF. The proposed approach may be advantageously configured to maximize the magnetic reluctance encountered by the asynchronous harmonics while having essentially no impact on the useful or synchronous MMF component thus maximizing the power density of the machine.
The description below illustrates one example embodiment of a fault tolerant permanent magnet machine that may benefit from aspects of the present invention. It will be appreciated that aspects of the present invention are not limited to the example embodiment described below.
A rotor 24 including a rotor core 26 may be disposed outside and concentric with the stator 12. In one embodiment, the rotor core 26 includes axial segments that are electrically insulated from each other to reduce eddy current losses. The rotor core 26 includes a laminated back-core structure 28 disposed around a plurality of permanent magnets 30. Back-core structure 28 is generally referred to in the art as a “back-iron” structure. Back-core structure 28 may comprise a plurality of stacked laminations. As described in more detail below, “lamination” refers to a thin ring or circumferentially-segmented structure, a plurality of which are typically stacked together along a rotor axis to form a machine component.
In accordance with aspects of the present invention, each back-core lamination may include a plurality of high-reluctance regions 50 arranged to attenuate the asynchronous magnetic flux components while avoiding the synchronous magnetic flux components, which result from the spatial harmonic components of the fractional-slot concentrated windings of the machine.
As illustrated in
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It will be appreciated that the plurality of high-reluctance regions (e.g., openings or gaps) may be adapted for providing optional rotor cooling conduits. For example, as shown in
In operation, aspects of the present invention provide an improved back-core structure as may be used in electromotive machines involving fractional slot pitch concentrated windings. The back-core arrangement may be configured with high reluctance regions suitably positioned to reduce asynchronous magnetic flux components and in turn reduce electromagnetic losses associated with such asynchronous components while having virtually no effect on the synchronous magnetic flux (useful MMF) components. For example, this may be helpful to reduce the cooling needs of the rotor of the machine and/or improve the power density of the machine.
While only certain features of the invention have been illustrated and described herein, many modifications and changes will occur to those skilled in the art. It is, therefore, to be understood that the appended claims are intended to cover all such modifications and changes as fall within the true spirit of the invention.