METHOD TO OPTIMIZE ENGINE OPERATION USING ACTIVE FUEL MANAGEMENT
A method for operating an internal combustion engine comprises providing a vehicle having an internal combustion gasoline engine including multiple cylinders and wherein the engine is operating in a deactivated cylinder mode, receiving a torque request if a cylinder reactivation torque smoothing mode is active, setting a variable torque ratio to 1.0 if the torque request is greater than a fast exit threshold torque, setting the variable torque ratio to 0.0 if the torque request is less than a slow exit threshold torque, setting the variable torque ratio to a value between 0.0 and 1.0 if the torque request is between the fast exit threshold torque and slow exit threshold torque, and calculating a component of final engine output torque.
This application is a continuation of U.S. patent application Ser. No. 15/251,645 filed on Aug. 30, 2016. The disclosure of the above application is incorporated herein by reference.
INTRODUCTIONThe disclosure relates generally to automobile engine control and more particularly to operation of an internal combustion engine while the engine is being run in an active fuel management mode for optimization of fuel efficiency.
A typical internal combustion engine is a combination of systems that individually serve a specific function. The air intake system provides throttled air to the engine. The fuels system stores, transports, and regulates fuel flow into the combustion chambers of the engine. The ignition system provides spark for igniting the air/fuel mixture. The power conversion system converts the chemical energy of combustion into work that is transferred to the tires of the vehicle. Other systems perform functions that improve fuel economy and emissions, cool the engine and provide heat to the vehicle cabin, or run other accessories such as power steering or air conditioning.
The size of the engine is typically tailored to the size and purpose of the vehicle. For example, a small light car built for fuel efficiency may include a small three cylinder or four cylinder engine having 1.5 to 2.0 Liters of displacement. Alternatively, a full-size pick-up truck or van that is purposely built for carrying tools and pulling machinery will require an engine having a larger displacement and more cylinders. A displacement of 4.5 L and above in a V8 or V10 configuration provides the torque and power required to carry and pull heavy loads. However, there are occasions of use when such a vehicle will not require all of the torque available in the V8 or V10 engine. It is during such occasions that it becomes desirable from a fuel efficiency standpoint to simply not use all of the cylinders that are available. Thus, a method of operating the engine has been developed to improve fuel economy while maintaining the overall capacity of torque available to the vehicle operator.
Active fuel management methods have been developed which include shutting off fuel delivery to a cylinder when the torque demand on the engine is low. However, there are many issues with controlling an engine and powertrain when using active fuel management. Drivability, torque demand, Noise and Vibration must all be maintained or improved while at the same time improving fuel economy. Thus, while current active fuel management controls achieve their intended purpose, the need for new and improved active fuel management controls which ensure the vehicle operators expectations are achieved is essentially constant. Accordingly, there is a need for an improved and reliable active fuel management controls system and method.
SUMMARYAn internal combustion engine control method is provided, the method includes providing a vehicle having an internal combustion gasoline engine including multiple cylinders and wherein the engine is operating in a deactivated cylinder mode, receiving a torque request if a cylinder reactivation torque smoothing mode is active, setting a variable torque ratio to rmax if the torque request is greater than a fast exit threshold torque tfast, setting the variable torque ratio to rmin if the torque request is less than a slow exit threshold torque tslow, setting the variable torque ratio to a value between rmax and rmin if the torque request is between the fast exit threshold torque and slow exit threshold torque, and calculating a final engine output torque.
In one example of the present disclosure, calculating a final engine output torque further comprises calculating a final engine output torque according to the formula:
tf=tslow+r(tfast−tslow), and
wherein tfast is the fast exit threshold torque, tslow is the slow exit threshold torque, and r is the variable torque ratio.
In another example of the present disclosure, setting the variable torque ratio to a value between rmin and rmax if the torque request is between the fast exit threshold torque tfast and slow exit threshold torque tslow further comprises setting the variable torque ratio to a value proportional to the torque request if the torque request is between the fast exit threshold torque tfast and slow exit threshold torque tslow.
In yet another example of the present disclosure, setting a variable torque ratio to rmax if the torque request is greater than a fast exit threshold torque tfast further comprises setting a variable torque ratio to 1.0 if the torque request is greater than a fast exit threshold torque.
In yet another example of the present disclosure, setting the variable torque ratio to rmin if the torque request is less than a slow exit threshold torque tslow further comprises setting the variable torque ratio to 0.0 if the torque request is less than a slow exit threshold torque.
In yet another example of the present disclosure, setting a variable torque ratio to rmax if the torque request is greater than a fast exit threshold torque tfast further comprises setting the variable torque ratio to rmax if the torque request is greater than the fast exit threshold torque tfast wherein the fast exit threshold torque tfast is derived from calibration tables having a fast exit threshold torque tfast value for a plurality of operational parameters.
In yet another example of the present disclosure, setting a variable torque ratio to rmin if the torque request is less than a slow exit threshold torque tslow further comprises setting the variable torque ratio to rmin if the torque request is less than the slow exit threshold torque tslow wherein the slow exit threshold torque tslow is derived from calibration tables having a slow exit threshold torque tslow value for a plurality of operational parameters.
Another internal combustion engine control method is provided, the method includes providing a vehicle having an internal combustion gasoline engine including multiple cylinders and wherein the engine is operating in a deactivated cylinder mode, receiving a torque request if a cylinder reactivation torque smoothing mode is active, setting a variable torque ratio to rmax if the torque request is greater than a fast exit threshold torque, and setting the variable torque ratio to a value less than rmax if the torque request is less than the fast exit threshold torque.
In one example of the present disclosure, the method further comprises calculating a component of final engine output torque using the variable torque ratio.
In another example of the present disclosure, calculating the component of final engine output torque tf further comprises calculating the component of final engine output torque according to the formula:
tf=r(tfast), and
wherein tfast is the fast exit threshold torque and r is the variable torque ratio.
In yet another example of the present disclosure, setting the variable torque ratio to a value below rmax if the torque request is below the fast exit threshold torque further comprises setting the variable torque ratio to a value proportional to the torque request if the torque request is below the fast exit threshold torque.
In yet another example of the present disclosure, setting the variable torque ratio to rmax if the torque request is greater than a fast exit threshold torque further comprises setting the variable torque ratio r to 1.0 if the torque request is greater than the fast exit threshold torque.
Another internal combustion engine control method is provided. The method includes providing a vehicle having an internal combustion gasoline engine including multiple cylinders and wherein the engine is operating in a deactivated cylinder mode, receiving a torque request if a cylinder reactivation torque smoothing mode is active, setting a variable torque ratio to rmin if the torque request is less than a slow exit threshold torque, and setting the variable torque ratio to a value greater than rmin if the torque request is greater than the slow exit threshold torque.
In one example of the present disclosure, the method further comprises calculating a component of final engine output torque using the variable torque ratio.
In another example of the present disclosure, calculating the component of final engine output torque tf further comprises calculating the component of final engine output torque according to the formula:
tf=r(tslow), and
wherein tslow is the slow exit threshold torque and r is the variable torque ratio.
In yet another example of the present disclosure, setting the variable torque ratio to a value greater than rmin if the torque request is greater than the slow exit threshold torque further comprises setting the variable torque ratio to a value proportional to the torque request if the torque request is greater than the slow exit threshold torque.
In yet another example of the present disclosure, setting the variable torque ratio to rmin if the torque request is less than a slow exit threshold torque further comprises setting the variable torque ratio to 0.0 if the torque request is less than the slow exit threshold torque.
The above features and advantages and other features and advantages of the present disclosure are readily apparent from the following detailed description when taken in connection with the accompanying drawings.
The drawings described herein are for illustration purposes only and are not intended to limit the scope of the present disclosure in any way.
The following description is merely exemplary in nature and is not intended to limit the present disclosure, application, or uses.
With reference to
Turning now to
The air intake system 26 includes a plurality of air ducts 44 and a throttle valve 46. The throttle valve 46 controls the amount of airflow passing into the air intake system 26 while the air ducts 44 direct incoming air to be used in the combustion process into the combustion chamber 42.
The valvetrain system 32 includes an intake valve 48 and an exhaust valve 50 in each cylinder 38 and a mechanism (not shown) for actuating the intake valve 48 and exhaust valve 50. The intake valve 48 opens to allow communication between the air ducts 44 of the air intake system 26 and the combustion chamber 42. In the present example, there is only one intake valve 48 and one exhaust valve 50 in each combustion chamber 42. However, a valvetrain system 32 having more than one intake valve 48 or exhaust valve 50 in each cylinder 38 may be considered without departing from the scope of the present disclosure.
The fuel delivery system 22 includes a pressurized fuel source or fuel pump 52, fuel lines 54, and fuel injectors 56. The fuel pump 52 is disposed in the fuel tank (not shown) located elsewhere in the vehicle. The fuel pump 52 pressurizes the fuel lines 54 which deliver pressurized fuel to the fuel injectors 56. The fuel injectors 56 are disposed in the air ducts 44 of the air intake system 26 proximate the intake valve 48. The fuel injectors 56 may also be located in the combustion chamber 42 wherein the fuel is injected directly into the combustion chamber 42.
The ignition system 24 includes spark plugs 58, ignition coils 60, and ignition wires 62. A single spark plug 58 is disposed in each of the combustion chambers 42. An ignition coil 60 is disposed electrically between the powertrain control module 20 and each of the spark plugs 58. The powertrain control module 20 sends a low voltage electric signal to the ignition coils 60 where the signal is stepped to a high-voltage signal required to create a spark and then sent to the spark plugs 58 through the ignition wires 62.
The exhaust system 30 collects exhaust gases from the combustion process in the combustion chamber 42 and directs the gases through a series of after-treatment mechanisms such as catalytic converters and mufflers (not shown). Some of the exhaust gases can be diverted back to the intake system for improved combustion and fuel economy.
The powertrain control module 20 is electronically connected to at least the engine 12 and transmission 14 and is preferably an electronic control device having a preprogrammed digital computer or processor, control logic, memory used to store data, and at least one I/O peripheral. The control logic includes a plurality of logic routines or sequence for monitoring, manipulating, and generating data. The powertrain control module 20 controls the operation of each of the engine 12 and transmission 14. The control logic may be implemented in hardware, software, or a combination of hardware and software. For example, control logic may be in the form of program code that is stored on the electronic memory storage and executable by the processor. The powertrain control module 20 receives the output signals of several sensors throughout the transmission 14 and engine 12, performs the control logic and sends command signals to the engine 12 and transmission 14. The engine 12 and transmission 14 receive command signals from the powertrain control module 20 and converts the command signals to control actions operable in the engine 12 and transmission 14. Some of the control actions include but are not limited to increasing engine 12 speed, changing air/fuel ratio, changing transmission 14 gear ratios, etc, among many other control actions.
For example, a control logic implemented in software program code that is executable by the processor of the powertrain control module 20 includes control logic for implementing a method of operating the engine 12 in an active fuel management or cylinder deactivation mode or method. The cylinder deactivation mode is initiated to improve fuel consumption by cutting off fuel delivery to or deactivating selected cylinders while torque demand on the engine is less than the maximum torque available from the engine. A portion of the cylinder deactivation mode is controlling the operation of the engine as the engine is operating under cylinder deactivation mode and the vehicle operator is requesting additional torque. Such a portion of engine control is a cylinder reactivation torque smoothing control method 100. An important goal of the cylinder reactivation torque smoothing control method 100 is to provide a smooth, measured increase in torque from the engine 12 as the operator is requesting an increase in torque delivery to the wheels 18.
A schematic of the engine control operation is illustrated in
If the torque request treq is between the fast torque exit threshold tfast and the slow exit threshold torque tslow, a sixth step 112 sets the variable torque reduction ratio r equal to the proportion that the torque request is between the fast and slow exit threshold torques tfast, tslow. Thus, the final torque engine output tf is set in the seventh step 114 as the slow exit threshold torque tslow+the variable torque reduction ratio r times the difference of the fast exit threshold torque tfast and the slow exit threshold torque tslow.
tf=tslow+r(tfast−tslow)
Once the final torque output tf is calculated for a particular torque request treq, spark control is used to smoothly increase the torque output from the previously deactivated cylinders 38. For example, for any particular engine, the fast and slow exit threshold torques tfast, tslow are particular numbers for a given set of operating parameters found on calibrated tables stored in the powertrain control module 20. In this manner, the cylinder reactivation torque smoothing control method 100 is capable of controlling engines of many displacements and configurations without departing from the scope of the disclosure.
While examples have been described in detail, those familiar with the art to which this disclosure relates will recognize various alternative designs and examples for practicing the disclosed structure within the scope of the appended claims.
Claims
1. A method for operating an internal combustion engine, the method comprising:
- providing a vehicle having an internal combustion gasoline engine including multiple cylinders and wherein the engine is operating in a deactivated cylinder mode;
- receiving a torque request if a cylinder reactivation torque smoothing mode is active;
- setting a variable torque ratio to rmax if the torque request is greater than a fast exit threshold torque, and
- setting the variable torque ratio to a value less than rmax if the torque request is less than the fast exit threshold torque.
2. The method of operating an internal combustion engine of claim 1 further comprising calculating a component of final engine output torque using the variable torque ratio.
3. The method of operating an internal combustion engine of claim 2 wherein calculating the component of final engine output torque tf further comprises calculating the component of final engine output torque according to the formula:
- tf=r(tfast), and
- wherein tfast is the fast exit threshold torque and r is the variable torque ratio.
4. The method of operating an internal combustion engine of claim 1 wherein setting the variable torque ratio to a value below rmax if the torque request is below the fast exit threshold torque further comprises setting the variable torque ratio to a value proportional to the torque request if the torque request is below the fast exit threshold torque.
5. The method of operating an internal combustion engine of claim 1 wherein setting the variable torque ratio to rmax if the torque request is greater than a fast exit threshold torque further comprises setting the variable torque ratio r to 1.0 if the torque request is greater than the fast exit threshold torque.
6. A method for operating an internal combustion engine, the method comprising:
- providing a vehicle having an internal combustion gasoline engine including multiple cylinders and wherein the engine is operating in a deactivated cylinder mode;
- receiving a torque request if a cylinder reactivation torque smoothing mode is active;
- setting a variable torque ratio to rmin if the torque request is less than a slow exit threshold torque, and
- setting the variable torque ratio to a value greater than rmin if the torque request is greater than the slow exit threshold torque.
7. The method of operating an internal combustion engine of claim 6 further comprising calculating a component of final engine output torque using the variable torque ratio.
8. The method of operating an internal combustion engine of claim 7 wherein calculating the component of final engine output torque tf further comprises calculating the component of final engine output torque according to the formula:
- tf=r(tslow), and
- wherein tslow is the slow exit threshold torque and r is the variable torque ratio.
9. The method of operating an internal combustion engine of claim 6 wherein setting the variable torque ratio to a value greater than rmin if the torque request is greater than the slow exit threshold torque further comprises setting the variable torque ratio to a value proportional to the torque request if the torque request is greater than the slow exit threshold torque.
10. The method of operating an internal combustion engine of claim 6 wherein setting the variable torque ratio to rmin if the torque request is less than a slow exit threshold torque further comprises setting the variable torque ratio to 0.0 if the torque request is less than the slow exit threshold torque.
11. A method for operating an internal combustion engine, the method comprising:
- providing a vehicle having an internal combustion gasoline engine including multiple cylinders and wherein the engine is operating in a deactivated cylinder mode;
- receiving a torque request if a cylinder reactivation torque smoothing mode is active;
- setting a variable torque ratio to rmax if the torque request is greater than a fast exit threshold torque, and
- setting the variable torque ratio to a value less than rmax if the torque request is less than the fast exit threshold torque.
12. The method of operating an internal combustion engine of claim 11 further comprising setting the variable torque ratio to rmin if the torque request is less than a slow exit threshold torque.
13. The method of operating an internal combustion engine of claim 12 further comprising setting the variable torque ratio to a value between rmin and rmax if the torque request is between the fast exit threshold torque and the slow exit threshold torque.
14. The method of operating an internal combustion engine of claim 13 further comprising calculating a component of final engine output torque using the variable torque ratio.
15. The method of operating an internal combustion engine of claim 14 wherein calculating the component of final engine output torque tf further comprises calculating the component of final engine output torque according to the formula:
- tf=tslow+r(tfast−tslow), and
- wherein tfast is the fast exit threshold torque, tslow is the slow exit threshold torque, and r is the variable torque ratio.
16. The method of operating an internal combustion engine of claim 15 wherein setting the variable torque ratio to a value between rmin and rmax if the torque request is between the fast exit threshold torque and the slow exit threshold torque further comprises setting the variable torque ratio to a value proportional to the torque request if the torque request is between the fast exit threshold torque and the slow exit threshold torque.
17. The method of operating an internal combustion engine of claim 16 wherein setting the variable torque ratio to rmax if the torque request is greater than a fast exit threshold torque further comprises setting the variable torque ratio to 1.0 if the torque request is greater than the fast exit threshold torque.
18. The method of operating an internal combustion engine of claim 17 wherein setting the variable torque ratio to rmin if the torque request is less than a slow exit threshold torque further comprises setting the variable torque ratio to 0.0 if the torque request is less than the slow exit threshold torque.
19. The method of operating an internal combustion engine of claim 18 wherein setting the variable torque ratio to rmax if the torque request is greater than a fast exit threshold torque further comprises setting the variable torque ratio to rmax if the torque request is greater than the fast exit threshold torque wherein the fast exit threshold torque is derived from calibration tables having a fast exit threshold torque value for one of a plurality of operational parameters.
20. The method of operating an internal combustion engine of claim 19 wherein setting the variable torque ratio to rmin if the torque request is less than a slow exit threshold torque further comprises setting the variable torque ratio to rmin if the torque request is less than the slow exit threshold torque wherein the slow exit threshold torque is derived from calibration tables having a slow exit threshold torque value for one of a plurality of operational parameters.
Type: Application
Filed: Jan 7, 2019
Publication Date: May 9, 2019
Inventors: Chad D. Kromrey (Perry, MI), Zhong Li (Novi, MI), Nigel K. Hyatt (West Bloomfield, MI), Andrew J. Harkenrider (Oakland Township, MI)
Application Number: 16/241,179