Methods and systems are provided for periodically activating a vehicle engine such that issues that may occur responsive to engine inactivity, such as rust and the sticking of components of the valve train, may be prevented. In one example, a vehicle engine increment off timer is used to monitor a d
Methods and systems are provided for periodically activating a vehicle engine such that issues that may occur responsive to engine inactivity, such as rust and the sticking of components of the valve train, may be prevented. In one example, a vehicle engine increment off timer is used to monitor a duration wherein the vehicle engine has not been active, and responsive to expiration of the timer, spinning the engine unfueled in reverse while concurrently activating an onboard pump to direct air and fuel vapor to be stored in a fuel vapor canister. In this way, periodic engine lubrication operations may be conducted that do not require the use of fueled engine operation, thereby improving fuel economy and reducing undesired evaporative emissions.
대표청구항▼
1. A method comprising: propelling a motor vehicle by at least an internal combustion engine which rotates in a default direction by combusting fuel; andresponsive to an indication of a vehicle engine-off duration greater than an engine-off threshold, spinning the engine unfueled in a reverse direct
1. A method comprising: propelling a motor vehicle by at least an internal combustion engine which rotates in a default direction by combusting fuel; andresponsive to an indication of a vehicle engine-off duration greater than an engine-off threshold, spinning the engine unfueled in a reverse direction opposite the default direction, wherein the engine-off duration greater than an engine-off threshold includes a predetermined amount of time. 2. The method of claim 1, further comprising: storing fuel vapors in a fuel vapor canister, the fuel vapor canister configured within a vehicle evaporative emissions system; andwherein spinning the engine unfueled in reverse includes routing air and fuel vapors to the fuel vapor canister. 3. The method of claim 2, wherein spinning the engine unfueled in reverse generates a vacuum in an exhaust manifold of the engine and a positive pressure in an intake manifold of the engine; and wherein the vacuum in the exhaust manifold of the engine and positive pressure in the intake manifold routes air and fuel vapors in the exhaust manifold and intake manifold to the fuel vapor canister. 4. The method of claim 2, further comprising: applying a negative pressure to the evaporative emissions system and an intake manifold of the engine by activating an onboard vacuum pump; andwherein routing air and fuel vapors to the fuel vapor canister comprises activating the onboard vacuum pump to direct air and fuel vapors to the fuel vapor canister. 5. The method of claim 4, further comprising: sequestering blow by vapors in a crankcase of the engine;fluidically coupling the crankcase to the intake manifold of the engine by a vacuum-actuated positive crankcase ventilation valve;wherein activating the vacuum pump opens the vacuum-actuated positive crankcase ventilation valve; andwherein routing air and fuel vapors to the fuel vapor canister comprises routing blow by vapors in the crankcase of the engine to the fuel vapor canister. 6. The method of claim 4, further comprising: storing fuel vapors in an air intake system hydrocarbon trap in the intake manifold of the engine; andwherein activating the vacuum pump desorbs fuel vapors from the air intake system hydrocarbon trap, the desorbed fuel vapors routed to the fuel vapor canister. 7. The method of claim 1, wherein spinning the engine unfueled in reverse further comprises: operating an electric motor to rotate the engine in the opposite direction from engine rotation during fueled engine operation. 8. The method of claim 3, further comprising: fluidically coupling the fuel vapor canister to an engine intake manifold by opening a canister purge valve positioned between the vapor canister and the intake manifold;fluidically coupling the fuel vapor canister to atmosphere by opening a canister vent valve;fluidically coupling the engine intake manifold to atmosphere through a throttle;fluidically coupling the fuel vapor canister to a fuel tank by opening a fuel tank isolation valve; andwherein routing air and fuel vapors to the fuel vapor canister includes closing the throttle, closing the fuel tank isolation valve, opening the canister purge valve, and opening the canister vent valve. 9. The method of claim 2, further comprising: monitoring a fuel vapor canister loading state; andwherein commencing spinning the engine unfueled in reverse further comprises the fuel vapor canister loading state below a threshold fuel vapor canister loading state. 10. The method of claim 9, wherein the threshold fuel vapor canister loading state comprises a fuel vapor canister loading state where a predetermined amount of fuel vapor may be added to the fuel vapor canister to be stored without exceeding a loading capacity of the fuel vapor canister. 11. The method of claim 10, wherein monitoring the fuel vapor canister loading state further comprises: monitoring the fuel vapor canister loading state during the spinning the engine unfueled in reverse; andstopping the spinning the engine unfueled in reverse responsive to the fuel vapor canister loading state above another threshold. 12. A method comprising: propelling a vehicle by either a battery driven electric motor (battery mode) or by an internal combustion engine;during operation in the battery mode, in response to a first condition discontinuing the battery mode and activating fueled engine combustion operation with the engine rotating in a default direction; andduring operation in the battery mode, in response to a second condition activating unfueled engine operation in reverse with the engine rotating in a reverse direction from the default direction, wherein the second condition further comprises monitoring the engine and indicating an engine-off duration via an engine increment off timer, and activating unfueled engine operation in reverse responsive to an indication that a predetermined amount of time has elapsed without an engine-on event. 13. The method of claim 12, wherein the first condition further comprises: activating fueled engine operation responsive to a driver requested vehicle wheel torque request greater than a threshold, or a battery state of charge lower than a battery charge threshold. 14. The method of claim 12, wherein activating unfueled engine operation in reverse comprises operating an electric motor to rotate the engine in a reverse direction. 15. The method of claim 12, further comprising: storing fuel vapors in a fuel vapor canister, the fuel vapor canister configured within a vehicle evaporative emissions control system;applying a negative pressure to the evaporative emissions control system and an intake manifold of the engine by activating an onboard vacuum pump; andwherein activating unfueled engine operation in reverse comprises activating the onboard pump to route air and fuel vapors to the fuel vapor canister. 16. The method of claim 15, further comprising: fluidically coupling the fuel vapor canister to an engine intake manifold by opening a canister purge valve;fluidically coupling the fuel vapor canister to atmosphere by opening a canister vent valve;fluidically coupling the engine intake manifold to atmosphere through a throttle;fluidically coupling the fuel vapor canister to a fuel tank by opening a fuel tank isolation valve; andwherein routing air and fuel vapors to the fuel vapor canister includes closing the throttle, closing the fuel tank isolation valve, opening the canister purge valve, and opening the canister vent valve. 17. A hybrid system for a vehicle which may be driven by either an electric motor or an internal combustion engine, comprising: the electric motor coupled to a battery and a drivetrain of a vehicle;the internal combustion engine coupled to the vehicle drivetrain and the electric motor, the engine having an intake manifold;a fuel vapor recovery system having a vapor storage canister coupled to a fuel tank of the vehicle through a fuel tank isolation valve, coupled to the intake manifold through a purge valve, and coupled to atmosphere through a canister vent valve;a controller, storing instructions in non-transitory memory, that when executed, cause the controller to: control the electric motor to propel the vehicle and shut off the engine while the vehicle is propelled by the electric motor; and, in response to the engine being off for an engine-off duration greater than an engine-off threshold includes a predetermined number of miles driven by the vehicle, rotating the engine by the electric motor in a reverse direction from a direction rotated during combustion and disabling fuel delivery to the engine to prevent combustion. 18. The system recited in claim 17 further comprising a vacuum pump coupled to the canister vent valve and wherein the controller: while rotating the engine in the reverse direction without fuel, activates the vacuum pump and opens the purge valve and closes a throttle coupled to the intake manifold to force fuel vapors or oil vapors from the engine to the vapor storage canister for adsorption therein.
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이 특허에 인용된 특허 (9)
Boggs, David Lee; Robichaux, Jerry D.; Peters, Mark William; Kotre, Stephen John, Controlled engine shutdown for a hybrid electric vehicle.
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