Adaptive electric motors and generators providing improved performance and efficiency

US 20040021437A1
Filed: 02/06/2003
Published: 02/05/2004
Est. Priority Date: 07/31/2002
Status: Abandoned Application

First Claim

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1. A multiphase electric machine comprising:

a rotor, a stator, the stator comprising a plurality of stator core elements, the plurality of stator core elements being arranged in groups, each group of stator core elements comprising at least one stator core element, each group of stator core elements being associated with a corresponding one of the phases of the multiphase machine, the stator core elements in each group being structurally separated from the stator core elements in each other group, and a controller for controlling electrical flow in each group of stator core elements independently of electrical flow in each other group, whereby each phase of the multiphase machine is controllable independently of each other phase.

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Abstract

An adaptive architecture for electric motors, generators and other electric machines. An adaptive electric machine provides optimal performance by dynamically adapting its controls to changes in user inputs, machine operating conditions and machine operating parameters. Isolating the machine'"'"'s electromagnetic circuits allows effective control of more independent machine parameters, enabling greater freedom to optimize and providing adaptive motors and generators that are cheaper, smaller, lighter, more powerful, and more efficient than conventional designs. An electric vehicle with in-wheel adaptive motors enables delivery of higher power with lower unsprung mass, giving better torque-density. The motor control system can adapt to the vehicle'"'"'s operating conditions, including starting, accelerating, turning, braking, and cruising at high speeds, thereby consistently providing higher efficiency. A wind powered adaptive generator can adapt to changing wind conditions, consistently providing optimal performance. An adaptive architecture may improve performance in a wide variety of electric machine applications, particularly those requiring optimal efficiency over a range of operating conditions.

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26 Claims

1. A multiphase electric machine comprising:
- a rotor, a stator, the stator comprising a plurality of stator core elements, the plurality of stator core elements being arranged in groups, each group of stator core elements comprising at least one stator core element, each group of stator core elements being associated with a corresponding one of the phases of the multiphase machine, the stator core elements in each group being structurally separated from the stator core elements in each other group, and a controller for controlling electrical flow in each group of stator core elements independently of electrical flow in each other group, whereby each phase of the multiphase machine is controllable independently of each other phase.

2. A multiphase electric machine comprising:
- a rotor, a stator, the stator comprising a plurality of stator core elements, the plurality of stator core elements being arranged in groups, each group of stator core elements comprising at least one stator core element, each group of stator core elements being associated with a corresponding one of the phases of the multiphase machine, the stator core elements in each group being structurally and electromagnetically separated from the stator core elements in each other group, and a controller for controlling electrical flow in each group of stator core elements independently of electrical flow in each other group, whereby each phase of the multiphase machine is controllable independently of each other phase, thereby establishing relative rotation between the rotor and the stator at a speed and a torque that are dynamically selectable.
- View Dependent Claims (3, 8, 9, 10)
- - 3. The machine of claim 2 wherein the machine has an efficiency and wherein the controller is operable to optimize the efficiency of the machine for each selected torque and speed.
  - 8. The machine of claim 2 wherein the machine has a weight, wherein the torque and weight define a ratio, and wherein the ratio has a value not less than 20 Nm/kg.
  - 9. The machine of claim 2 wherein the machine has a volume, wherein the torque and volume define a ratio, and wherein the ratio has a value not less than 39,000 N/m².
  - 10. The machine of claim 2 wherein the machine is operable at a speed ranging between at least 0 RPM and 500 RPM, and at an efficiency that is not less than 80% at every speed between at least 50 RPM and 300 RPM.

4. A multiphase electric machine comprising:
- a first member, a second member, the second member comprising a plurality of core elements, the plurality of core elements being arranged in groups, each group of core elements comprising at least one core element, each group of core elements being associated with a corresponding one of the phases of the multiphase machine, the core elements in each group being structurally and electromagnetically separated from the core elements in each other group, and a controller for controlling electrical flow in each group of core elements independently of electrical flow in each other group, whereby each phase of the multiphase machine is controllable independently of each other phase, thereby establishing relative movement between the first member and the second member in a direction and with a force that are dynamically selectable.

5. A multiphase electric machine comprising:
- a first member, a second member, at least one of the first and second members comprising a plurality of core elements, the plurality of core elements being arranged in groups, each group of core elements comprising at least one core element, each group of core elements being associated with a corresponding one of the phases of the multiphase machine, the core elements in each group being structurally and electromagnetically separated from the core elements in each other group, and a controller for controlling electrical flow in each group of core elements independently of electrical flow in each other group, whereby each phase of the multiphase machine is controllable independently of each other phase, thereby establishing relative movement between the first member and the second member in a direction and with a force that are dynamically selectable.

6. A multiphase electric machine comprising:
- at least one member, the at least one member comprising a plurality of core elements, the plurality of core elements being arranged in groups, each group of core elements comprising at least one core element, each group of core elements being associated with a corresponding one of the phases of the multiphase machine, the core elements in each group being structurally and electromagnetically separated from the core elements in each other group, and a controller for controlling electrical flow in each group of core elements independently of electrical flow in each other group, whereby each phase of the multiphase machine is controllable independently of each other phase, thereby establishing movement of the at least one member in a direction and with a force that are dynamically selectable.

7. A multiphase electric machine comprising at least one member, the at least one member comprising a plurality of core elements, the plurality of core elements being arranged in groups, each group of core elements comprising at least one core element, each group of core elements being associated with a corresponding one of the phases of the multiphase machine, the core elements in each group being sufficiently separated, at least one of structurally or electromagnetically, from the core elements in each other group to enable control of electrical flow in each group of core elements independently of electrical flow in each other group, whereby each phase of the multiphase machine is controllable independently of each other phase, thereby establishing movement of the at least one member in a direction and with a force that are dynamically selectable.

11. A method comprising:
- providing a multiphase electric machine comprising at least a rotor and a stator, the stator comprising a plurality of stator core elements, arranging the plurality of stator core elements in groups, each group of stator core elements comprising at least one stator core element, each group of stator core elements being associated with a corresponding one of the phases of the multiphase machine, structurally separating the stator core elements in each group from the stator core elements in each other group, and controlling electrical flow in each group of stator core elements independently of electrical flow in each other group, whereby each phase of the multiphase machine is controllable independently of each other phase.

12. A method comprising:
- providing a multiphase electric machine comprising at least a rotor and a stator, the stator comprising a plurality of stator core elements, arranging the plurality of stator core elements in groups, each group of stator core elements comprising at least one stator core element, each group of stator core elements being associated with a corresponding one of the phases of the multiphase machine, structurally and electromagnetically separating the stator core elements in each group from the stator core elements in each other group, and controlling electrical flow in each group of stator core elements independently of electrical flow in each other group, whereby each phase of the multiphase machine is controllable independently of each other phase, thereby establishing relative rotation between the rotor and the stator at a speed and a torque that are dynamically selectable.
- View Dependent Claims (13, 18, 19, 20)
- - 13. The method of claim 12 wherein the machine has an efficiency and wherein the step of controlling electrical flow in each group of stator core elements comprises controlling electrical flow to optimize the efficiency of the machine for each selected torque and speed.
  - 18. The method of claim 12 wherein the machine has a weight, wherein the torque and weight define a ratio, and wherein the ratio has a value not less than 20 Nm/kg.
  - 19. The method of claim 12 wherein the machine has a volume, wherein the torque and volume define a ratio, and wherein the ratio has a value not less than 39,000 N/m².
  - 20. The method of claim 12 wherein the machine is operable at a speed ranging between at least 0 RPM and 500 RPM, and at an efficiency that is not less than 80% at every speed between at least 50 RPM and 300 RPM.

14. A method comprising:
- providing a multiphase electric machine comprising at least a first member and a second member, the second member comprising a plurality of core elements, arranging the plurality of core elements in groups, each group of core elements comprising at least one core element, each group of core elements being associated with a corresponding one of the phases of the multiphase machine, structurally and electromagnetically separating the core elements in each group from the core elements in each other group, and controlling electrical flow in each group of core elements independently of electrical flow in each other group, whereby each phase of the multiphase machine is controllable independently of each other phase, thereby establishing relative movement between the first member and the second member in a direction and with a force that are dynamically selectable.

15. A method comprising:
- providing a multiphase electric machine comprising at least a first member and a second member, at least one of the first and second members comprising a plurality of core elements, arranging the plurality of core elements in groups, each group of core elements comprising at least one core element, each group of core elements being associated with a corresponding one of the phases of the multiphase machine, structurally and electromagnetically separating the core elements in each group from the core elements in each other group, and controlling electrical flow in each group of core elements independently of electrical flow in each other group, whereby each phase of the multiphase machine is controllable independently of each other phase, thereby establishing relative movement between the first member and the second member in a direction and with a force that are dynamically selectable.

16. A method comprising:
- providing a multiphase electric machine comprising at least one member, the at least one member comprising a plurality of core elements, arranging the plurality of core elements in groups, each group of core elements comprising at least one core element, each group of core elements being associated with a corresponding one of the phases of the multiphase machine, structurally and electromagnetically separating the core elements in each group from the core elements in each other group, and controlling electrical flow in each group of core elements independently of electrical flow in each other group, whereby each phase of the multiphase machine is controllable independently of each other phase, thereby establishing movement of the at least one member in a direction and with a force that are dynamically selectable.

17. A method comprising:
- providing a multiphase electric machine comprising at least one member, the at least one member comprising a plurality of core elements, arranging the plurality of core elements in groups, each group of core elements comprising at least one core element, each group of core elements being associated with a corresponding one of the phases of the multiphase machine, at least one of structurally separating and electromagnetically separating the core elements in each group from the core elements in each other group to enable control of electrical flow in each group of core elements independently of electrical flow in each other group, whereby each phase of the multiphase machine is controllable independently of each other phase, thereby establishing movement of the at least one member in a direction and with a force that are dynamically selectable.

21. A method of making a multiphase electric machine, comprising:
- providing at least a rotor and a stator, the stator comprising a plurality of stator core elements, arranging the plurality of stator core elements in groups, each group of stator core elements comprising at least one stator core element, each group of stator core elements being associated with a corresponding one of the phases of the multiphase machine, structurally separating the stator core elements in each group from the stator core elements in each other group, and controlling electrical flow in each group of stator core elements independently of electrical flow in each other group, whereby each phase of the multiphase machine is controllable independently of each other phase.

22. A method of making a multiphase electric machine, comprising:
- providing at least a rotor and a stator, the stator comprising a plurality of stator core elements, arranging the plurality of stator core elements in groups, each group of stator core elements comprising at least one stator core element, each group of stator core elements being associated with a corresponding one of the phases of the multiphase machine, structurally and electromagnetically separating the stator core elements in each group from the stator core elements in each other group, and controlling electrical flow in each group of stator core elements independently of electrical flow in each other group, whereby each phase of the multiphase machine is controllable independently of each other phase, thereby establishing relative rotation between the rotor and the stator at a speed and a torque that are dynamically selectable.

23. A method of making a multiphase electric machine, comprising:
- providing at least a first member and a second member, the second member comprising a plurality of core elements, arranging the plurality of core elements in groups, each group of core elements comprising at least one core element, each group of core elements being associated with a corresponding one of the phases of the multiphase machine, structurally and electromagnetically separating the core elements in each group from the core elements in each other group, and controlling electrical flow in each group of core elements independently of electrical flow in each other group, whereby each phase of the multiphase machine is controllable independently of each other phase, thereby establishing relative movement between the first member and the second member in a direction and with a force that are dynamically selectable.

24. A method of making a multiphase electric machine, comprising:
- providing at least a first member and a second member, at least one of the first and second members comprising a plurality of core elements, arranging the plurality of core elements in groups, each group of core elements comprising at least one core element, each group of core elements being associated with a corresponding one of the phases of the multiphase machine, structurally and electromagnetically separating the core elements in each group from the core elements in each other group, and controlling electrical flow in each group of core elements independently of electrical flow in each other group, whereby each phase of the multiphase machine is controllable independently of each other phase, thereby establishing relative movement between the first member and the second member in a direction and with a force that are dynamically selectable.

25. A method of making a multiphase electric machine, comprising:
- providing at least one member, the at least one member comprising a plurality of core elements, arranging the plurality of core elements in groups, each group of core elements comprising at least one core element, each group of core elements being associated with a corresponding one of the phases of the multiphase machine, structurally and electromagnetically separating the core elements in each group from the core elements in each other group, and controlling electrical flow in each group of core elements independently of electrical flow in each other group, whereby each phase of the multiphase machine is controllable independently of each other phase, thereby establishing movement of the at least one member in a direction and with a force that are dynamically selectable.

26. A method of making a multiphase electric machine, comprising:
- providing at least one member, the at least one member comprising a plurality of core elements, arranging the plurality of core elements in groups, each group of core elements comprising at least one core element, each group of core elements being associated with a corresponding one of the phases of the multiphase machine, at least one of structurally separating and electromagnetically separating the core elements in each group from the core elements in each other group to enable control of electrical flow in each group of core elements independently of electrical flow in each other group, whereby each phase of the multiphase machine is controllable independently of each other phase, thereby establishing movement of the at least one member in a direction and with a force that are dynamically selectable.

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Current Assignee
BluWav Systems LLC (Magna International Incorporated)
Original Assignee
BluWav Systems LLC (Magna International Incorporated)
Inventors
Maslov, Boris A., Pyntikov, Alexander

Application Number

US10/359,305
Publication Number

US 20040021437A1
Time in Patent Office

Days
Field of Search
US Class Current

318/254
CPC Class Codes

B60L 2200/26   Rail vehicles

B60L 2210/20   AC to AC converters

B60L 2220/18   Reluctance machines

B60L 2220/44   Wheel Hub motors, i.e. inte...

B60L 8/00   Electric propulsion with po...

H02K 1/141   consisting of C-shaped cores

H02K 1/187   to inner stators

H02K 11/33   Drive circuits, e.g. power ...

H02K 16/04   Machines with one rotor and...

H02K 21/22   with magnets rotating aroun...

H02K 2213/06   Machines characterised by t...

H02K 2213/09   Machines characterised by t...

H02K 2213/12   Machines characterised by t...

H02K 29/00   Motors or generators having...

H02K 3/28   Layout of windings or of co...

H02K 7/1838   Generators mounted in a nac...

H02P 2209/07   Trapezoidal waveform

H02P 23/0077   Characterised by the use of...

H02P 25/08   Reluctance motors

H02P 6/34   Modelling or simulation for...

Y02T 10/64 : Electric machine technologi...

Y02T 10/7072 : Electromobility specific ch...

Y02T 10/72 : Electric energy management ...

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Adaptive electric motors and generators providing improved performance and efficiency

First Claim

2 Assignments

0 Petitions

Accused Products

Abstract

Citations

26 Claims

Specification

Solutions

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Adaptive electric motors and generators providing improved performance and efficiency

First Claim

2 Assignments

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Accused Products

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Abstract

Citations

26 Claims

Specification

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