CLOSED-LOOP POWER CONTROL SYSTEM FOR HYBRID ELECTRIC VEHICLES

US 20040168840A1
Filed: 02/27/2003
Published: 09/02/2004
Est. Priority Date: 02/27/2003
Status: Active Grant

First Claim

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1. A method for controlling a hybrid powertrain for an automotive vehicle having a driver controlled engine, an electric motor, a battery, a generator connected to the battery and a gear system that establishes two power sources for distributing torque to vehicle traction wheels, the method comprising the steps of:

delivering engine torque to a first torque input element of the gear system, delivering reaction torque of the gear system to the motor and generator and delivering torque from a torque output element of the gear system to the traction wheels thereby establishing a power split in a first power source configuration;

delivering torque from the motor and generator through the gear system to the traction wheels with the engine deactivated thereby establishing a second power source configuration; and

coordinating power delivery from the first and second power sources whereby a response to driver demand for power will optimize driveline efficiency and performance without exceeding power limits for the engine and the battery.

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Abstract

A control system and control method for a hybrid electric vehicle powertrain having an engine, an electric motor and an electric generator with gearing for effecting split power distribution from separate power sources. Power delivery to vehicle traction wheels is coordinated to meet a driver'"'"'s demand for power as much as possible without violating predefined maximum and minimum powertrain limits, including the limits of the battery subsystem.

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8 Claims

1. A method for controlling a hybrid powertrain for an automotive vehicle having a driver controlled engine, an electric motor, a battery, a generator connected to the battery and a gear system that establishes two power sources for distributing torque to vehicle traction wheels, the method comprising the steps of:
- delivering engine torque to a first torque input element of the gear system, delivering reaction torque of the gear system to the motor and generator and delivering torque from a torque output element of the gear system to the traction wheels thereby establishing a power split in a first power source configuration;
  
  delivering torque from the motor and generator through the gear system to the traction wheels with the engine deactivated thereby establishing a second power source configuration; and
  
  coordinating power delivery from the first and second power sources whereby a response to driver demand for power will optimize driveline efficiency and performance without exceeding power limits for the engine and the battery.
- View Dependent Claims (2, 3, 4, 5, 7, 8)
- - 2. The method set forth in claim 1 including the step of braking the generator to establish a parallel mechanical torque flow path to the traction wheels with a fixed gear system ratio.
  - 3. The method set forth in claim 1 including the steps of determining a driver demand for power as a function of traction wheel speed and driver torque demand;
    - determining whether the driver demand for power is within predetermined maximum and minimum system power limits; and
      
      delivering battery power to the transmission gearing to complement the driver demand for power when the driver demand for power is outside the engine power limits.
  - 4. The method set forth in claim 3 including the steps of determining whether a request for battery power to complement engine power is within predetermined battery power maximum and minimum limits and controlling battery power to avoid exceeding battery power limits thereby preventing the battery from overcharging or over-discharging.
  - 5. The method as set forth in claim 3 wherein the step of determining driver demand for power includes the step of accounting for electrical losses in the powertrain whereby the effective demand for power is the sum of the driver demand for power and electrical power losses.
  - 7. The control system set forth in claim 5 wherein the vehicle system controller includes means for limiting power distribution to the traction wheels, following a driver demand for power, to power values within predefined power maximum and minimum limits.
  - 8. The control system set forth in claim 7 wherein the vehicle system controller includes means for incrementing the driver demand for power by an amount equal to electrical power losses in the driveline whereby the incremented driver demand for power is limited to the predefined maximum and minimum power limits.

6. A closed-loop power control system for a powertrain for a hybrid electric vehicle comprising:
- an engine, a battery, a motor and a generator defining an electric drive system;
  
  a planetary gear unit having a sun gear, a ring gear and a planetary carrier, the engine being connected to the carrier and the sun gear being connected to the generator;
  
  a geared torque flow path defined by the electric drive system extending to vehicle traction wheels, a torque input element of the electric drive system being connected to the motor;
  
  a vehicle system controller for coordinating power distribution from the engine and the battery to effect optimal powertrain performance within predefined battery power charging and discharging limits.

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Current Assignee
Ford Global Technologies, LLC (Ford Motor Company)
Original Assignee
Ford Global Technologies, LLC (Ford Motor Company)
Inventors
Syed, Fazal Urrahman, Smith, David Estes, Kuang, Ming Lang

Granted Patent

US 6,991,053 B2
Time in Patent Office

Days
Field of Search
US Class Current

180/65.2
CPC Class Codes

B60K 6/445   Differential gearing distri...

B60L 2240/12   Speed

B60L 2240/421   Speed

B60L 2240/423   Torque

B60L 2240/441   Speed

B60L 2240/443   Torque

B60L 2240/461   Speed

B60L 2240/662   Temperature

B60L 50/16   with provision for separate...

B60L 50/61   by batteries charged by eng...

B60L 58/14   Preventing excessive discha...

B60L 58/15   Preventing overcharging

B60W 10/06   including control of combus...

B60W 10/08   including control of electr...

B60W 10/26   for electrical energy, e.g....

B60W 20/00   Control systems specially a...

B60W 20/10   Controlling the power contr...

B60W 20/13   in order to stay within bat...

B60W 2520/10   Longitudinal speed

B60W 2540/10   Accelerator pedal position

Y02T 10/40 : Engine management systems

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 ...

Y02T 90/16 : Information or communicatio...

Y10S 903/93 : Conjoint control of differe...

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CLOSED-LOOP POWER CONTROL SYSTEM FOR HYBRID ELECTRIC VEHICLES

First Claim

3 Assignments

0 Petitions

Accused Products

Abstract

44 Citations

8 Claims

Specification

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CLOSED-LOOP POWER CONTROL SYSTEM FOR HYBRID ELECTRIC VEHICLES

First Claim

3 Assignments

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Subscription Required

0 Petitions

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Accused Products

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Abstract

44 Citations

8 Claims

Specification

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Solutions

Use Cases

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