An electrical induction motor may include a stator with a plurality of circumferentially spaced slots, and N windings installed in the slots and each configured to be connected between two current inputs from an inverter, with a phase angle difference between the two current inputs equal to H×180°/N
An electrical induction motor may include a stator with a plurality of circumferentially spaced slots, and N windings installed in the slots and each configured to be connected between two current inputs from an inverter, with a phase angle difference between the two current inputs equal to H×180°/N, wherein H=a harmonic of a current drive waveform supplied by the inverter to the windings. Each of the N windings may be installed in the plurality of slots to form a top layer of winding and a bottom layer of winding, with a phase angle of the current flowing through the top layer of winding in each slot being aligned with a phase angle of current flowing through the bottom layer of winding at a first, higher harmonic, and out of alignment at a second, lower harmonic.
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1. An electrical induction motor configured to receive N separate current inputs at N separate terminals from N output phases of a N-phase inverter, the motor comprising: a stator comprising a plurality of circumferentially spaced slots;a rotor rotatably mounted within the stator; andN windings conn
1. An electrical induction motor configured to receive N separate current inputs at N separate terminals from N output phases of a N-phase inverter, the motor comprising: a stator comprising a plurality of circumferentially spaced slots;a rotor rotatably mounted within the stator; andN windings connected to the N separate terminals and a plurality of contactors, wherein each of the plurality of contactors is configured to be selectively opened or closed in a circuit including the N windings to selectively connect the N windings together in one of a mesh configuration or a star configuration;each of the N windings being configured to be selectively connected between two of the N separate current inputs, with a phase angle difference between the two separate current inputs equal to H×180°/N, wherein H=a harmonic of a current drive waveform supplied by the inverter to the windings; andeach of the N windings being installed in the plurality of slots to form a top layer of winding in a radially outer portion of a first one of the slots and a bottom layer of winding in a radially inner portion of a second one of the slots, and configured to receive a current flowing through each of the N windings such that a phase angle of the current flowing through the top layer of winding installed in each slot is aligned with a phase angle of current flowing through the bottom layer of winding installed in the slot at a first, higher harmonic of the current drive waveform and is out of alignment at a second, lower harmonic of the current drive waveform. 2. The electrical induction motor of claim 1, wherein N equals 9. 3. The electrical induction motor of claim 1, wherein each of the N windings forms a top layer of winding in a first group of at least two circumferentially adjacent slots and a bottom layer of winding in a second group of at least two circumferentially adjacent slots. 4. The electrical induction motor of claim 1, wherein the first and second slots are circumferentially spaced apart from each other by less than 90 degrees. 5. The electrical induction motor of claim 1, wherein N equals 9, and wherein the motor is further configured to receive one or more signals indicative of a request to operate the motor to start an engine, and configured to process the one of more signals in order to selectively receive a third harmonic of the current drive waveform generated by the nine phase inverter. 6. The electrical induction motor of claim 1, further configured to receive one or more signals indicative of a request to operate the motor to start an engine, and configured to process the one or more signals in order to selectively open or close each of the plurality of contactors to establish the star configuration. 7. The electrical induction motor of claim 1, wherein N equals 9, and wherein the motor is further configured to receive one or more signals indicative of a request to operate the motor as an alternator to generate electricity, and configured to process the one of more signals in order to selectively receive a first, fundamental harmonic of the current drive waveform generated by the nine phase inverter. 8. The electrical induction motor of claim 1, further configured to receive one or more signals indicative of a request to operate the motor as an alternator to generate electricity, and configured to process the one or more signals in order to selectively open or close each of the plurality of contactors to establish the mesh configuration. 9. The electrical induction motor of claim 1, wherein N equals 9, and wherein the phase angle of current flowing through the top layer of winding installed in each slot is aligned with a phase angle of current flowing through the bottom layer of winding installed in the slot at a third harmonic of the drive waveform, and is 120 degrees out of alignment at a first, fundamental harmonic of the current drive waveform. 10. A method for configuring a N-phase electrical induction motor comprising a stator and a rotor, and including N windings in a plurality of circumferentially spaced slots in the stator, and a plurality of contactors arranged in a circuit including the N windings, the method comprising: selectively opening or closing each of the plurality of contactors to selectively connect the N windings together in one of a mesh configuration or a star configuration;selectively connecting each of the N windings between two of N separate current inputs from N output phases of a N-phase inverter, with a phase angle difference between the two separate current inputs equal to H×180°/N, wherein H=a harmonic of a current drive waveform supplied by the inverter to the windings;installing each of the N windings in the plurality of circumferentially spaced slots to form a top layer of winding in a radially outer portion of a first one of the slots and a bottom layer of winding in a radially inner portion of a second one of the slots; andsupplying a current from the inverter through each of the N windings such that a phase angle of current flowing through the top layer of winding installed in each slot is aligned with a phase angle of current flowing through the bottom layer of winding installed in the slot at a first, higher harmonic of the current drive waveform and is out of alignment at a second, lower harmonic of the current drive waveform. 11. The method of claim 10, wherein N equals 9. 12. The method of claim 10, further comprising installing each of the N windings to form a top layer of winding in a first group of at least two circumferentially adjacent slots and a bottom layer of winding in a second group of at least two circumferentially adjacent slots. 13. The method of claim 10, further comprising installing each of the windings in a radially outer portion of a first slot and a radially inner portion of a second slot circumferentially spaced from the first slot by less than 90 degrees. 14. The method of claim 10, further comprising: configuring a nine phase electrical induction motor to receive one or more signals indicative of a request to operate the motor to start an engine; andprocessing the one of more signals in order to selectively receive a third harmonic of the current drive waveform generated by a nine phase inverter. 15. The method of claim 10, further comprising: receiving one or more signals indicative of a request to operate the motor to start an engine; andprocessing the one or more signals in order to selectively open or close each of the plurality of contactors to establish the star configuration. 16. The method of claim 10, further comprising: configuring a nine phase electrical induction motor to receive one or more signals indicative of a request to operate the motor as an alternator to generate electricity; andprocessing the one of more signals in order to selectively receive a first, fundamental harmonic of the current drive waveform generated by a nine phase inverter. 17. The method of claim 10, further comprising: receiving one or more signals indicative of a request to operate the motor as an alternator to generate electricity; andprocessing the one or more signals in order to selectively open or close each of the plurality of contactors to establish the mesh configuration. 18. The method of claim 10, further comprising: configuring a nine phase electrical induction motor to receive a phase angle of current flowing through the top layer of winding installed in each slot that is aligned with a phase angle of current flowing through the bottom layer of winding installed in the slot at a third harmonic of the current drive waveform, and is 120 degrees out of alignment at a first, fundamental harmonic of the current drive waveform. 19. An electrical system for a machine, the electrical system comprising: a N-phase inverter; anda N-phase induction motor configured to receive N separate current inputs at N separate terminals from N output phases of the N-phase inverter;the N-phase induction motor comprising: a stator, wherein the stator comprises a plurality of circumferentially spaced slots;a rotor rotatably mounted within the stator; andN windings connected to the N separate terminals and a plurality of contactors, wherein each of the plurality of contactors is configured to be selectively opened or closed in a circuit including the N windings to selectively connect the N windings together in one of a mesh configuration or a star configuration,wherein each of the N windings is configured to be selectively connected between two of the N separate current inputs, with a phase angle difference between the two separate current inputs equal to H×180°/N, wherein H=a harmonic of a current drive waveform supplied by the inverter to the windings, andwherein each of the N windings is installed in at least two of the plurality of slots to form a top layer of winding in a radially outer portion of a first one of the at least two slots and a bottom layer of winding in a radially inner portion of a second one of the at least two slots, and configured to receive a current flowing through the winding such that a phase angle of the current flowing through the top layer of winding installed in the first slot is aligned with a phase angle of current flowing through the bottom layer of winding installed in the first slot at a first, higher harmonic of the current drive waveform and is out of alignment at a second, lower harmonic of the current drive waveform. 20. The electrical system of claim 19, wherein the N-phase induction motor is a nine phase induction motor further configured to: receive one or more first signals indicative of a request to operate the motor to start an engine;process the one or more first signals in order to selectively receive the third harmonic of the current drive waveform generated by the nine phase inverter;receive one or more second signals indicative of a request to operate the motor as an alternator to generate electricity; andprocess the one or more second signals in order to selectively receive the first, fundamental harmonic of the current drive waveform generated by the nine phase inverter.
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이 특허에 인용된 특허 (5)
Lipo Thomas A. (Middleton WI) Osama Mohamed (Madison WI), Inverter-controlled induction machine with an extended speed range.
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