Methods and systems are provided for monitoring a fuel vapor recovery system including a fuel tank isolation valve coupled between a fuel tank and a canister. During selected conditions, the valve is modulated and pressure pulsations in the fuel vapor recovery system are monitored. Valve degradation
Methods and systems are provided for monitoring a fuel vapor recovery system including a fuel tank isolation valve coupled between a fuel tank and a canister. During selected conditions, the valve is modulated and pressure pulsations in the fuel vapor recovery system are monitored. Valve degradation is identified based on correlations between the valve modulation and the resultant pressure pulsations.
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1. A method of monitoring a fuel vapor recovery system, comprising, modulating a fuel tank isolation valve (FTIV) coupled between a fuel tank and a canister of the fuel vapor recovery system; andindicating FTIV degradation based on pressure pulsations upstream and/or downstream of the FTIV responsiv
1. A method of monitoring a fuel vapor recovery system, comprising, modulating a fuel tank isolation valve (FTIV) coupled between a fuel tank and a canister of the fuel vapor recovery system; andindicating FTIV degradation based on pressure pulsations upstream and/or downstream of the FTIV responsive to the modulation, wherein the modulation is performed during an engine-off condition in response to obtaining a threshold pressure difference across the FTIV, and wherein the modulation includes intermittently opening the FTIV with a duty cycle based on a bandwidth of the valve, wherein an increased modulation duty cycle is applied during higher pressure differential conditions relative to the threshold pressure difference, and a decreased modulation duty cycle is applied during lower pressure differential conditions relative to the threshold pressure difference. 2. The method of claim 1, wherein the indication includes, during a first condition when the pressure difference across the FTIV is higher, indicating FTIV degradation based on pressure pulsations only upstream, or only downstream, of the FTIV; andduring a second condition when the pressure difference across the FTIV is lower, indicating FTIV degradation based on pressure pulsations upstream and downstream of the FTIV. 3. The method of claim 1, wherein the pressure pulsations upstream of the FTIV are estimated by a first pressure sensor coupled to the fuel tank, and wherein the pressure pulsations downstream of the FTIV are estimated by a second pressure sensor coupled to the canister. 4. The method of claim 1, wherein the indication includes, indicating degradation if a frequency ratio of pressure pulses to valve pulses is lower than a threshold. 5. The method of claim 1, wherein the indication includes, filtering the pressure pulsations through a first, band-pass filter and a second, notch filter, and indicating degradation if a difference between output from the first and second filters is less than a threshold. 6. The method of claim 1, further comprising, in response to FTIV degradation, disabling leak detection in the fuel vapor recovery system for a duration. 7. A method of monitoring a fuel vapor recovery system, comprising, modulating a fuel tank isolation valve (FTIV) coupled between a fuel tank and a canister of the fuel vapor recovery system; andindicating FTIV degradation based on pressure pulsations upstream and downstream of the FTIV responsive to the modulation, wherein the modulation is a periodic modulation at a selected frequency, and the indication is based on an amplitude of the pressure pulsations at the selected frequency. 8. The method of claim 7, wherein the pressure pulsations upstream of the FTIV are estimated by a first pressure sensor coupled to the fuel tank, and wherein the pressure pulsations downstream of the FTIV are estimated by a second pressure sensor coupled to the canister. 9. The method of claim 7, wherein the indication includes, indicating degradation if a frequency ratio of pressure pulses to valve pulses is lower than a threshold. 10. The method of claim 7, wherein the indication includes, filtering the pressure pulsations through a first, band-pass filter and a second, notch filter, and indicating degradation if a difference between output from the first and second filters is less than a threshold. 11. The method of claim 7, further comprising, in response to FTIV degradation, disabling leak detection in the fuel vapor recovery system for a duration. 12. A method of operating a fuel vapor recovery system including a fuel tank coupled to a canister through a fuel tank isolation valve, comprising, during a first engine-off diurnal cycle, with a pressure difference across the valve being higher than a threshold, modulating the valve with a duty cycle based on a bandwidth of the valve, the modulating including intermittently opening the valve with the duty cycle; andindicating valve degradation based on pressure pulsations upstream and/or downstream of the valve responsive to the modulation; andduring a second engine-off diurnal cycle, immediately following the first diurnal cycle, performing a leak detection operation if no valve degradation is indicated in the first diurnal cycle. 13. The method of claim 12, wherein an increased modulation duty cycle is applied during higher pressure differential conditions, and a decreased modulation duty cycle is applied during lower pressure differential conditions. 14. The method of claim 13, further comprising, stopping valve modulation in response to one or more of an engine restart request and a canister purge request. 15. The method of claim 13, wherein the pressure pulsations are estimated by a pressure sensor coupled to at least one of the fuel tank and the canister. 16. The method of claim 13, wherein, during a first condition, the indication is based on a frequency ratio of the pressure pulsations to the valve modulation;during a second condition, the indication is based on a difference between an output of the pressure pulsations through a band-pass filter and a notch filter; andduring a third condition, the indication is based on each of the frequency ratio and the difference.
DeBastos, Timothy; Kacewicz, John Michael; Bohr, Scott; Pearce, Russell Randall; Kragh, Christopher; Sullivan, Patrick; Euliss, William; Kluzner, Michael Igor, Method and system for fuel vapor control.
Pearce, Russell Randall; Bohr, Scott; Kragh, Christopher; DeBastos, Timothy; Sullivan, Patrick; Kerns, James Michael; Olson, Chad Michael, Method and system for fuel vapor control.
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