CONTROL OF AN ALTERNATOR-STARTER FOR A HYBRID ELECTRIC VEHICLE HAVING A DISCONNECTED HIGH-VOLTAGE BATTERY

US 20100225258A1
Filed: 02/23/2010
Published: 09/09/2010
Est. Priority Date: 03/09/2009
Status: Active Grant

First Claim

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1. An electric circuit for a hybrid powertrain system, comprising:

a multiphase bridge inverter electrically connected to a high-voltage energy storage system via positive and negative sides of a high-voltage DC power bus;

a multiphase asynchronous AC machine electrically connected to the multiphase bridge inverter;

a high-voltage DC link capacitor electrically connected between the positive and negative sides of the high-voltage DC power bus;

a low-voltage battery electrically connected to a gate drive bias power supply; and

a gate drive pre-charge circuit electrically connected between the gate drive bias power supply and the multiphase bridge inverter;

wherein the low-voltage battery electrically charging the high-voltage DC link capacitor via the gate drive bias power supply and the gate drive pre-charge circuit when the high-voltage energy storage system is disconnected from the high-voltage DC power bus.

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Abstract

A hybrid powertrain system includes an electric motor/generator unit having a multiphase asynchronous AC machine electrically connected to a multiphase bridge inverter. A high-voltage capacitor is electrically connected between positive and negative sides of a high-voltage DC power bus. High-voltage DC bus pre-charge circuits are electrically connected between gate drive bias power supplies and the multiphase bridge inverter. A low-voltage battery electrically charges the high-voltage DC link capacitor via the gate drive bias power supplies and the high-voltage DC bus pre-charge circuits when the high-voltage energy storage system is disconnected from the high-voltage DC power bus.

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18 Claims

1. An electric circuit for a hybrid powertrain system, comprising:
- a multiphase bridge inverter electrically connected to a high-voltage energy storage system via positive and negative sides of a high-voltage DC power bus;
  
  a multiphase asynchronous AC machine electrically connected to the multiphase bridge inverter;
  
  a high-voltage DC link capacitor electrically connected between the positive and negative sides of the high-voltage DC power bus;
  
  a low-voltage battery electrically connected to a gate drive bias power supply; and
  
  a gate drive pre-charge circuit electrically connected between the gate drive bias power supply and the multiphase bridge inverter;
  
  wherein the low-voltage battery electrically charging the high-voltage DC link capacitor via the gate drive bias power supply and the gate drive pre-charge circuit when the high-voltage energy storage system is disconnected from the high-voltage DC power bus.
- View Dependent Claims (2, 3, 4, 5, 6, 7, 8)
- - 2. The electric circuit for the hybrid powertrain system of claim 1, wherein the low-voltage battery electrically charges the high-voltage DC link capacitor to a voltage level sufficient to operationally magnetize a stator of the multiphase asynchronous AC machine.
  - 3. The electric circuit for the hybrid powertrain system of claim 1, wherein the low-voltage auxiliary battery electrically charges the high-voltage DC link capacitor to a predetermined voltage level when the high-voltage energy storage system is disconnected from the high-voltage DC power bus by operation of a high-voltage switch.
  - 4. The electric circuit for the hybrid powertrain system of claim 1, wherein the gate drive bias power supply provides DC electric power to a gate drive circuit for activation of a power transistor of the multiphase bridge inverter.
  - 5. The electric circuit for the hybrid powertrain system of claim 1, wherein the gate drive pre-charge circuit comprises a diode connected in series with a resistive device, the diode arranged to permit electric current flow from the gate drive bias power supply to the multiphase bridge inverter and restrict electric current flow from the multiphase bridge inverter to the gate drive bias power supply.
  - 6. The electric circuit for the hybrid powertrain system of claim 4, wherein the power transistor of the multiphase bridge inverter is connected between the positive side of the high-voltage DC power bus and one phase of the AC machine, and wherein the gate drive pre-charge circuit is connected between a high-voltage side of the gate drive bias power supply and the positive side of the high-voltage DC power bus.
  - 7. The electric circuit for the hybrid powertrain system of claim 4, wherein the power transistor of the multiphase bridge inverter is connected between the negative side of the high-voltage DC power bus and one phase of the AC machine, and wherein the gate drive pre-charge circuit is connected between a high-voltage side of the gate drive bias power supply and the one phase of the AC machine.
  - 8. The electric circuit for the hybrid powertrain system of claim 4, further comprising a control module controlling the gate drive circuit.

9. An electric circuit for a hybrid powertrain system, comprising:
- a multiphase bridge inverter electrically connected to a high-voltage energy storage system via positive and negative sides of a high-voltage DC power bus;
  
  a multiphase asynchronous AC machine electrically connected to the multiphase bridge inverter;
  
  a high-voltage switch when closed electrically connects the high-voltage energy storage system to the high-voltage DC power bus and when opened electrically disconnects the high-voltage energy storage system from the high-voltage DC power bus;
  
  a high-voltage DC link capacitor electrically connected between positive and negative sides of the high-voltage DC power bus;
  
  a low-voltage auxiliary battery electrically connected to a gate drive bias power supply providing DC electric power to a gate drive circuit, the gate drive circuit activating power transistors of the multiphase bridge inverter; and
  
  a gate drive pre-charge circuit electrically connected between the gate drive bias power supply and the multiphase bridge inverter;
  
  wherein the low-voltage auxiliary battery electrically charges the high-voltage DC link capacitor to a preferred voltage level via the gate drive bias power supply and the gate drive pre-charge circuit when a high-voltage switch is opened.
- View Dependent Claims (10, 11, 12, 13, 14, 15)
- - 10. The electric circuit for the hybrid powertrain system of claim 9, wherein the gate drive pre-charge circuit comprises a diode connected in series with a resistive device, the diode arranged to permit electric current flow from the gate drive bias power supply to the multiphase bridge inverter and restrict electric current flow from the multiphase bridge inverter to the gate drive bias power supply.
  - 11. The electric circuit for the hybrid powertrain system of claim 9, wherein the gate drive pre-charge circuit is connected between a high-voltage side of the gate drive bias power supply and the positive side of the high-voltage DC power bus.
  - 12. The electric circuit for the hybrid powertrain system of claim 9, wherein the gate drive pre-charge circuit is connected between a high-voltage side of the gate drive bias power supply and a node connecting a pair of switch devices of the multiphase bridge inverter.
  - 13. The electric circuit for the hybrid powertrain system of claim 9, wherein the preferred voltage level comprises a voltage sufficient to operate the multiphase asynchronous AC machine.
  - 14. The electric circuit for the hybrid powertrain system of claim 9, wherein the low-voltage auxiliary battery is configured to electrically charge the high-voltage DC link capacitor to a preferred voltage level via the gate drive bias power supplies and the gate drive pre-charge circuits when the high-voltage energy storage system is disconnected from the high-voltage DC power bus by operation of the high-voltage switch.
  - 15. The electric circuit for the hybrid powertrain system of claim 9, further comprising a control module configured to control operation of the plurality of gate drive circuits and the high-voltage switch.

16. Method for operating a hybrid powertrain system comprising an internal combustion engine mechanically coupled to an electric motor/generator unit, the electric motor/generator unit electrically connected to a bridge inverter including a high-voltage DC power bus having a positive high-voltage DC bus and a negative high-voltage DC bus, a high-voltage energy storage system selectively connectable to the high-voltage DC power bus, and a gate drive bias power supply providing DC electric power from a low-voltage battery to a gate drive circuit for activation of a power transistor of the multiphase bridge inverter, the method comprising:
- when the high-voltage energy storage system is disconnected from the high-voltage DC bus,electrically charging a capacitor between the positive high-voltage DC bus and the negative high-voltage DC bus with the gate drive bias power supply to establish an operational voltage of the motor/generator unit across the high-voltage DC bus; and
  
  spinning and operating the electric motor/generator unit in an electric power generating mode.
- View Dependent Claims (17, 18)
- - 17. The method of claim 16, wherein spinning the electric motor/generator unit comprises electrically connecting an engine starter motor to the low-voltage battery to transfer electric power thereto to start the engine from an engine-off state.
  - 18. The method of claim 16, wherein the high-voltage energy storage system is selectively disconnected from the high-voltage DC bus.

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Current Assignee
GM Global Technology Operations LLC (General Motors Company)
Original Assignee
GM Global Technology Operations Incorporated (Motors Liquidation Co. GUC Trust)
Inventors
Namuduri, Chandra S., Gopalakrishnan, Suresh, Van Maanen, Keith D., Ludwig, Bryan M.

Granted Patent

US 8,314,578 B2
Time in Patent Office

Days
Field of Search
US Class Current

318/400.300
CPC Class Codes

B60K 2006/268   Electric drive motor starts...

B60K 6/485   Motor-assist type

B60L 2210/40   DC to AC converters

B60L 2270/20   Inrush current reduction, i...

B60L 3/0046   relating to electric energy...

B60L 3/0069   relating to the isolation, ...

B60L 3/0092   with use of redundant eleme...

B60L 3/04   Cutting off the power suppl...

B60L 50/16   with provision for separate...

B60L 58/10   for monitoring or controlli...

B60L 58/20   having different nominal vo...

H02P 2201/07   DC-DC step-up or step-down ...

H02P 27/06   using dc to ac converters o...

Y02T 10/62   Hybrid vehicles

Y02T 10/64   Electric machine technologi...

Y02T 10/70   Energy storage systems for ...

Y02T 10/7072   Electromobility specific ch...

Y02T 10/72   Electric energy management ...

CONTROL OF AN ALTERNATOR-STARTER FOR A HYBRID ELECTRIC VEHICLE HAVING A DISCONNECTED HIGH-VOLTAGE BATTERY

First Claim

4 Assignments

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Abstract

44 Citations

18 Claims

Specification

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CONTROL OF AN ALTERNATOR-STARTER FOR A HYBRID ELECTRIC VEHICLE HAVING A DISCONNECTED HIGH-VOLTAGE BATTERY

First Claim

4 Assignments

Subscription Required

Subscription Required

0 Petitions

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Accused Products

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Abstract

44 Citations

18 Claims

Specification

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Use Cases

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Others