Evaporative emission control system with reduced running losses
First Claim
1. A method of controlling a canister vent valve used in an evaporative emissions control system to reduce running losses during purging of fuel vapors from a charcoal canister to an air intake of an internal combustion engine, wherein the control system includes a purge valve connected between the canister and air intake, with the canister being connected to receive evaporated fuel from a fuel tank that is used to supply fuel to the engine, the method comprising the steps of:
- monitoring gas pressure within the fuel tank, closing the canister vent valve while the engine is operating and the purge valve is open when the pressure within the fuel tank exceeds a threshold, and opening the canister vent valve while the engine is operating and the purge valve is open when the pressure within the tank falls below a lower limit, whereby the canister vent valve can be held closed during purging until the pressure within the fuel tank drops to below the lower limit.
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Accused Products
Abstract
An evaporative emission control system that operates in a running loss mode and an active weathering mode during purge to substantially eliminate running losses during operation of an internal combustion engine. The evaporative emission control system includes a charcoal canister, a canister vent valve, and a purge valve that permits fuel vapors from the canister and engine fuel tank to be purged into the engine'"'"'s air intake manifold. The running loss mode operates to close the canister vent valve when the gas pressure within the fuel tank increases above a threshold. The vent valve is maintained closed until the fuel tank pressure drops below a lower limit. This prevents running losses by closing the vent when higher pressures are detected that cannot be reduced by purging under the current engine operating conditions. The active weathering mode cycles the canister vent valve open and closed when the volatility of the fuel is determined to be too high for the current ambient temperature. This cycling forces air changes within the fuel tank to accelerate the weathering of the volatile components in the fuel. Fuel volatility is estimated based on tank temperature and fuel vapor concentration. The maximum desired volatility is determined for the ambient temperature and the active weathering mode is begun when the estimated volatility exceeds the maximum desired volatility.
61 Citations
18 Claims
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1. A method of controlling a canister vent valve used in an evaporative emissions control system to reduce running losses during purging of fuel vapors from a charcoal canister to an air intake of an internal combustion engine, wherein the control system includes a purge valve connected between the canister and air intake, with the canister being connected to receive evaporated fuel from a fuel tank that is used to supply fuel to the engine, the method comprising the steps of:
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monitoring gas pressure within the fuel tank, closing the canister vent valve while the engine is operating and the purge valve is open when the pressure within the fuel tank exceeds a threshold, and opening the canister vent valve while the engine is operating and the purge valve is open when the pressure within the tank falls below a lower limit, whereby the canister vent valve can be held closed during purging until the pressure within the fuel tank drops to below the lower limit. - View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9)
periodically performing a leak diagnostic test of the charcoal canister and fuel tank, and in response to determining that a leak exists, entering into a second mode of operation in which said canister vent valve is maintained in an open position.
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3. The method of claim 1, wherein said threshold is greater than barometric pressure.
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4. The method of claim 3, wherein the evaporative emissions control system has plural modes of operation with said closing and opening steps being carried out when the evaporative emissions control system is in a first one of its modes of operation, wherein the method further comprises the steps of:
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periodically performing a leak diagnostic test of the charcoal canister and fuel tank, and in response to determining that a leak exists, decreasing said threshold to a value below barometric pressure.
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5. The method of claim 1, further comprising the steps of determining the pressure within the fuel tank using a pressure sensor and periodically performing a leak diagnostic test of the charcoal canister and fuel tank using said pressure sensor.
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6. The method of claim 1, further comprising the steps of placing the canister vent valve in an open condition in response to shutdown of the engine, whereby pressure within the fuel tank will be relieved via the charcoal canister and canister vent valve.
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7. The method of claim 1, wherein said opening step further comprises opening the canister vent valve if the pressure within the tank exceeds an upper limit.
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8. The method of claim 1, wherein said steps are carried out when the evaporative emission control system is in a first mode and wherein the control system has a second mode of operation that comprises the following steps:
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switching the canister vent valve to a closed condition, monitoring gas pressure within the fuel tank, opening the canister vent valve when the pressure is falls below a lower threshold, and closing the canister vent valve when the pressure exceeds an upper threshold.
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9. The method of claim 8, wherein said first mode comprises a running loss mode and the second mode comprises an active weathering mode.
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10. A method of controlling the quantity of fuel vapors in a fuel tank using an evaporative emissions control system that includes a charcoal canister for receiving fuel vapors from the tank, a purge valve that permits purging of the fuel vapors, and a canister vent valve that permits atmospheric air to flow into the canister, the method comprising the steps of:
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obtaining a first data value that is related to the temperature of fuel within the fuel tank, obtaining a second data value that is related to the concentration of fuel vapors within the tank, determining a third data value using said first and second data values, wherein said third data value is indicative of the volatility of the fuel within the fuel tank, obtaining a fourth data value that is related to the temperature of ambient air, determining a threshold using said fourth data value, and closing the canister vent valve if the third data value exceeds said threshold. - View Dependent Claims (11, 12, 13, 14, 15, 16)
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17. A method of controlling the quantity of fuel vapors in a fuel tank using an evaporative emissions control system that includes a charcoal canister for receiving fuel vapors from the tank, a purge valve that permits purging of the fuel vapors, and a canister vent valve that permits atmospheric air to flow into the canister, the method comprising the steps of:
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switching the canister vent valve to a closed condition, monitoring gas pressure within the fuel tank, opening the canister vent valve while the engine is operating and the purge valve is open when the pressure falls below a lower threshold, and closing the canister vent valve while the engine is operating and the purge valve is open when the pressure exceeds an upper threshold, wherein the upper threshold is above the lower threshold. - View Dependent Claims (18)
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Specification
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- Resources
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Current AssigneeDelphi Technologies, Inc. (BorgWarner Incorporated)
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Original AssigneeDelphi Technologies, Inc. (BorgWarner Incorporated)
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InventorsQiao, Ningsheng, Grieve, Malcolm James, Himes, Edward George
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Primary Examiner(s)Kamen, Noah P.
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Assistant Examiner(s)GIMIE, MAHMOUD
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Application NumberUS09/264,561Time in Patent Office729 DaysField of Search123/520, 123/198.D, 123/516, 123/518, 123/519US Class Current123/520CPC Class CodesF02M 25/08 adding fuel vapours drawn f...
