INCREASED FUEL ECONOMY MODE CONTROL SYSTEMS AND METHODS

US 20120029787A1
Filed: 07/28/2010
Published: 02/02/2012
Est. Priority Date: 07/28/2010
Status: Active Grant

First Claim

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1. An engine control system comprising:

a desired manifold absolute pressure (MAP) module that determines a desired MAP for operation of an engine in one of a cylinder deactivation mode and a low-lift mode based on a difference between a desired vacuum and an air pressure upstream of a throttle valve;

a MAP to torque module that determines a desired torque output of the engine for operation in the one of the cylinder deactivation mode and the low-lift mode based on the desired MAP;

a threshold determination module that determines an entry torque based on the desired torque output; and

a fuel economy (FE) mode module that selectively triggers operation in the one of the cylinder deactivation mode and the low-lift mode based on a comparison of the entry torque and a torque request.

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Abstract

An engine control system includes a desired manifold absolute pressure (MAP) module, a MAP to torque module, a threshold determination module, and a fuel economy (FE) mode module. The desired MAP module determines a desired MAP for operation of an engine in one of a cylinder deactivation mode and a low-lift mode based on a difference between a desired vacuum and an air pressure upstream of a throttle valve. The MAP to torque module determines a desired torque output of the engine for operation in the one of the cylinder deactivation mode and the low-lift mode based on the desired MAP. The threshold determination module determines an entry torque based on the desired torque output. The FE mode module selectively triggers operation in the one of the cylinder deactivation mode and the low-lift mode based on a comparison of the entry torque and a torque request.

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20 Claims

1. An engine control system comprising:
- a desired manifold absolute pressure (MAP) module that determines a desired MAP for operation of an engine in one of a cylinder deactivation mode and a low-lift mode based on a difference between a desired vacuum and an air pressure upstream of a throttle valve;
  
  a MAP to torque module that determines a desired torque output of the engine for operation in the one of the cylinder deactivation mode and the low-lift mode based on the desired MAP;
  
  a threshold determination module that determines an entry torque based on the desired torque output; and
  
  a fuel economy (FE) mode module that selectively triggers operation in the one of the cylinder deactivation mode and the low-lift mode based on a comparison of the entry torque and a torque request.
- View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10)
- - 2. The engine control system of claim 1 further comprising:
    - a noise, vibration, and harshness (NVH) torque determination module that determines an NVH torque,wherein an NVH value is greater than a predetermined value when an actual torque output of the engine during operation in the one of the cylinder deactivation mode and the low-lift mode is greater than the NVH torque; and
      
      a maximum torque module that sets a maximum torque output for operation in the one of the cylinder deactivation mode and the low-lift mode equal to one of the NVH torque and the desired torque output,wherein the threshold determination module determines the entry torque based on the maximum torque output.
  - 3. The engine control system of claim 2 wherein the maximum torque module sets the maximum torque output equal to a lesser one of the NVH torque and the desired torque output.
  - 4. The engine control system of claim 2 wherein the threshold determination module sets the entry torque further based on a gear ratio.
  - 5. The engine control system of claim 2 wherein the NVH torque determination module determines the NVH torque based on a gear ratio, an engine speed, and an ambient air temperature.
  - 6. The engine control system of claim 2 further comprising:
    - an actuation module that determines an air torque request based on the torque request; and
      
      an air control module that limits to the air torque request to the maximum torque output during operation in the one of the cylinder deactivation mode and the low-lift mode to determine a limited air torque request and that determines a desired MAP, a desired air per cylinder (APC), and a desired throttle area based on the limited air torque request.
  - 7. The engine control system of claim 2 wherein the threshold determination module further determines an exit torque based on the maximum torque output, andwherein the FE mode module selectively disables operation in the one of the cylinder deactivation mode and the low-lift mode based on a second comparison of the torque request and the exit torque.
  - 8. The engine control system of claim 1 further comprising:
    - a correction module that determines a MAP to torque correction based on a first difference between a first torque and a second torque, that determines the first torque using a first relationship between an actual APC and the first torque, and that determines the second torque using a second relationship between a measured MAP and the second torque,wherein the MAP to torque module determines an uncorrected desired torque output of the engine for operation in the one of the cylinder deactivation mode and the low-lift mode based on the desired MAP and determines the desired torque output based on the MAP to torque correction and the uncorrected desired torque.
  - 9. The engine control system of claim 8 wherein the MAP to torque module sets the desired torque output to a sum of the MAP to torque correction and the uncorrected desired torque.
  - 10. The engine control system of claim 8 further comprising:
    - a MAP to APC module that determines a desired air per cylinder (APC) for the engine during operation in the one of the cylinder deactivation mode and the low-lift mode based on the desired MAP;
      
      a MAP correction module that determines a corrected APC based on the desired APC and a MAP to APC correction; and
      
      an optimum spark timing module that determines an optimum spark timing based on the corrected APC;
      
      wherein the correction module further determines the MAP to APC correction based on a second difference between an estimated APC and the actual APC, andwherein the MAP to torque module determines the desired torque output further based on the optimum spark timing.

11. An engine control method comprising:
- determining a desired manifold absolute pressure (MAP) for operation of an engine in one of a cylinder deactivation mode and a low-lift mode based on a difference between a desired vacuum and an air pressure upstream of a throttle valve;
  
  determining a desired torque output of the engine for operation in the one of the cylinder deactivation mode and the low-lift mode based on the desired MAP;
  
  determining an entry torque based on the desired torque output; and
  
  selectively triggering operation in the one of the cylinder deactivation mode and the low-lift mode based on a comparison of the entry torque and a torque request.
- View Dependent Claims (12, 13, 14, 15, 16, 17, 18, 19, 20)
- - 12. The engine control method of claim 11 further comprising:
    - determining a noise, vibration, and harshness (NVH) torque,wherein an NVH value is greater than a predetermined value when an actual torque output of the engine during operation in the one of the cylinder deactivation mode and the low-lift mode is greater than the NVH torque;
      
      setting a maximum torque output for operation in the one of the cylinder deactivation mode and the low-lift mode equal to one of the NVH torque and the desired torque output; and
      
      determining the entry torque based on the maximum torque output.
  - 13. The engine control method of claim 12 further comprising setting the maximum torque output equal to a lesser one of the NVH torque and the desired torque output.
  - 14. The engine control method of claim 12 further comprising setting the entry torque further based on a gear ratio.
  - 15. The engine control method of claim 12 further comprising determining the NVH torque based on a gear ratio, an engine speed, and an ambient air temperature.
  - 16. The engine control method of claim 12 further comprising:
    - determining an air torque request based on the torque request;
      
      limiting to the air torque request to the maximum torque output during operation in the one of the cylinder deactivation mode and the low-lift mode to determine a limited air torque request; and
      
      determining a desired MAP, a desired air per cylinder (APC), and a desired throttle area based on the limited air torque request.
  - 17. The engine control method of claim 12 further comprising:
    - determining an exit torque based on the maximum torque output; and
      
      selectively disabling operation in the one of the cylinder deactivation mode and the low-lift mode based on a second comparison of the torque request and the exit torque.
  - 18. The engine control method of claim 11 further comprising:
    - determining a MAP to torque correction based on a first difference between a first torque and a second torque;
      
      determining the first torque using a first relationship between an actual APC and the first torque;
      
      determining the second torque using a second relationship between a measured MAP and the second torque;
      
      determining an uncorrected desired torque output of the engine for operation in the one of the cylinder deactivation mode and the low-lift mode based on the desired MAP; and
      
      determining the desired torque output based on the MAP to torque correction and the uncorrected desired torque.
  - 19. The engine control method of claim 18 further comprising setting the desired torque output to a sum of the MAP to torque correction and the uncorrected desired torque.
  - 20. The engine control method of claim 18 further comprising:
    - determining a desired air per cylinder (APC) for the engine during operation in the one of the cylinder deactivation mode and the low-lift mode based on the desired MAP;
      
      determining a corrected APC based on the desired APC and a MAP to APC correction;
      
      determining an optimum spark timing based on the corrected APC;
      
      determining the MAP to APC correction based on a second difference between an estimated APC and the actual APC; and
      
      determining the desired torque output further based on the optimum spark timing.

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Current Assignee
GM Global Technology Operations LLC (General Motors Company)
Original Assignee
GM Global Technology Operations Incorporated (General Motors Company)
Inventors
Whitney, Christopher E., Baur, Andrew W., Spitza, Alfred E. Jr., Li, Zhong, Kaiser, Jeffrey M.

Granted Patent

US 8,473,179 B2
Time in Patent Office

Days
Field of Search
US Class Current

701/102
CPC Class Codes

F01L 1/34   characterised by the provis...

F01L 13/0005   Deactivating valves

F02D 13/0207   changing valve lift or valv...

F02D 13/0219   by shifting the phase, i.e....

F02D 13/06   Cutting-out cylinders

F02D 2041/0012   with selective deactivation...

F02D 2200/0406   Intake manifold pressure

F02D 2200/0414   Air temperature

F02D 2250/18   Control of the engine outpu...

F02D 2250/22   by keeping a torque reserve...

F02D 41/0002   Controlling intake air

F02D 41/0087   Selective cylinder activati...

F02D 41/0225   in relation with the gear r...

F02D 41/1497   With detection of the mecha...

F02D 41/1498   measuring engine roughness

F02M 26/05   High pressure loops, i.e. w...

Y02T 10/12   Improving ICE efficiencies

Y02T 10/40   Engine management systems

INCREASED FUEL ECONOMY MODE CONTROL SYSTEMS AND METHODS

First Claim

4 Assignments

0 Petitions

Accused Products

Abstract

Citations

20 Claims

Specification

Solutions

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INCREASED FUEL ECONOMY MODE CONTROL SYSTEMS AND METHODS

First Claim

4 Assignments

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Subscription Required

0 Petitions

Subscription Required

Accused Products

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Abstract

Citations

20 Claims

Specification

Subscription Required

Solutions

Use Cases

Quick Links