Rationality diagnostic techniques for an intake oxygen sensor are utilized to detect sensor malfunction. A non-intrusive diagnostic technique includes passively detecting when an exhaust gas recirculation (EGR) valve position crosses low/high position thresholds, whereas an intrusive diagnostic tech
Rationality diagnostic techniques for an intake oxygen sensor are utilized to detect sensor malfunction. A non-intrusive diagnostic technique includes passively detecting when an exhaust gas recirculation (EGR) valve position crosses low/high position thresholds, whereas an intrusive diagnostic technique includes actively commanding the EGR valve to predetermined low/high positions. During a period after the EGR valve position reaches/crosses at least one of the low/high positions/position thresholds, respectively, maximum and minimum intake oxygen concentration is monitored. When the EGR valve position has crossed both the low/high positions/position thresholds and a difference between the maximum and minimum oxygen concentrations is less than a respective difference threshold, a malfunction of the intake oxygen sensor is detected. A malfunction indicator lamp (MIL) could be set to indicate the malfunction. The intrusive technique is additionally or alternatively implemented, such as part of a verification or backup to the non-intrusive technique.
대표청구항▼
1. A diagnostic system for a vehicle, the diagnostic system comprising: an intake oxygen sensor configured to measure an oxygen concentration in an induction system of an engine at a point downstream from an exhaust gas recirculation (EGR) port and upstream from a throttle valve;an EGR valve positio
1. A diagnostic system for a vehicle, the diagnostic system comprising: an intake oxygen sensor configured to measure an oxygen concentration in an induction system of an engine at a point downstream from an exhaust gas recirculation (EGR) port and upstream from a throttle valve;an EGR valve position sensor configured to measure a position of an EGR valve; anda controller configured to: operate the vehicle, including operating the EGR valve within a full range of potential positions;detect when the EGR valve position measured by the EGR valve position sensor has crossed first and second diagnostic positions, wherein a difference between the first and second diagnostic positions represent an acceptable range of EGR valve positions for determining an acceptable range of measurement of the intake oxygen sensor;during a first period (I) after detecting that the EGR valve position has crossed only one of the first and second diagnostic positions and (ii) before a first delayed time, determine first maximum and minimum oxygen concentrations measured by the intake oxygen sensor across the first period, the first delayed time being a time at which the EGR valve position crosses the other of the first and second diagnostic positions as adjusted by an exhaust gas transport delay time;after the first period, calculating a first actual range of measurement of the intake oxygen sensor, the first actual range of measurement being equal to a difference between the first maximum and minimum oxygen concentrations measured by the intake oxygen sensor during the first period;detect a first sensor range malfunction of the intake oxygen sensor when the first actual range of measurement is less than a difference threshold indicative of the acceptable range of measurement by the intake oxygen sensor; andin response to detecting the first sensor range malfunction of the intake oxygen sensor, actuate a malfunction indicator lamp (MIL). 2. The diagnostic system of claim 1, wherein the exhaust gas transport delay time is a time delay for exhaust gas to flow from the EGR valve to the intake oxygen sensor. 3. The diagnostic system of claim 1, wherein the controller is further configured to, during operation of the vehicle, verify at least one of: (i) no malfunctions of the EGR valve or the EGR valve position sensor;(ii) no circuit fault in the intake oxygen sensor or a heater associated therewith; and(iii) no communication issue between the intake oxygen sensor and the controller. 4. The diagnostic system of claim 1, wherein when the position of the EGR valve as measured by the EGR position sensor has not crossed both of the first and second diagnostic positions during a predetermined period, the controller is further configured to: adjust operation of the vehicle, including commanding the EGR valve to the first and second diagnostic positions based on feedback from the EGR valve position sensor;during a second period (I) after the EGR valve position reaches only one of the first and second diagnostic positions and (ii) before a second delayed time, determine second maximum and minimum oxygen concentrations from a second plurality of measured oxygen concentrations measured by the intake oxygen sensor across the second period, the second delayed time being a time at which the EGR valve position reaches the other of the first and second diagnostic positions as adjusted by the second exhaust gas transport delay time; andafter the second period, calculate a second actual range of measurement of the intake oxygen sensor, the second actual range of measurement being a difference between the second maximum and minimum oxygen concentrations measured by the intake oxygen sensor during the second period;detect a second sensor range malfunction of the intake oxygen sensor when the second actual range of measurement of the intake oxygen sensor is less than the difference threshold indicative of the acceptable range of measurement by the intake oxygen sensor. 5. The diagnostic system of claim 1, wherein the controller is further configured to, during operation of the vehicle, verify each of: (i) no malfunctions of the EGR valve or the EGR valve position sensor;(ii) no circuit fault in the intake oxygen sensor or a heater associated therewith; and(iii) no communication issue between the intake oxygen sensor and the controller. 6. A diagnostic system for a vehicle, the diagnostic system comprising: an intake oxygen sensor configured to measure an oxygen concentration in an induction system of an engine at a point downstream from an exhaust gas recirculation (EGR) port and upstream from a throttle valve;an EGR valve position sensor configured to measure a position of an EGR valve; anda controller configured to: operate the vehicle, including operating the EGR valve within a full range of potential positions; andwhen the position of the EGR valve, during a predetermined period, has not crossed both first and second diagnostic positions, wherein a difference between the first and second diagnostic positions represent an acceptable range of EGR valve positions for determining an acceptable range of measurement of the intake oxygen sensor: adjust operation of the vehicle, including commanding the EGR valve to the first and second diagnostic positions based on feedback from the EGR valve position sensor;during a first period (i) after the EGR valve position reaches only one of the first and second diagnostic positions and (ii) before a first delayed time, determine first maximum and minimum oxygen concentrations measured by the intake oxygen sensor, the first delayed time being a time at which the EGR valve position reaches the other of the first and second diagnostic positions as adjusted by an exhaust gas transport delay time;after the first period, calculate a first actual range of measurement of the intake oxygen sensor, the first actual range of measurement being equal to a difference between the first maximum and minimum oxygen concentrations measured by the intake oxygen sensor during the first period;detect a first sensor range malfunction of the intake oxygen sensor when the first actual range of measurement is less than a difference threshold indicative of the acceptable range of measurement by the intake oxygen sensor; andin response to detecting the first sensor range malfunction of the intake oxygen sensor, actuate a malfunction indicator lamp (MIL). 7. The diagnostic system of claim 6, wherein the exhaust gas transport delay time is a time delay for exhaust gas to flow from the EGR valve to the intake oxygen sensor. 8. The diagnostic system of claim 6, wherein the controller is further configured to, during operation of the vehicle, verify at least one of: (i) no malfunctions of the EGR valve or the EGR valve position sensor;(ii) no circuit fault in the intake oxygen sensor or a heater associated therewith; and(iii) no communication issue between the intake oxygen sensor and the controller. 9. The diagnostic system of claim 6, wherein the controller is further configured to during the operation of the vehicle, detect that the EGR valve position measured by the EGR valve position sensor has crossed both the first and second diagnostic positions during the predetermined period and, in response: during a second period (i) after detecting that the EGR valve position has crossed only one of the first and second diagnostic positions and (ii) before a second delayed time, determining second maximum and minimum oxygen concentrations measured by the intake oxygen sensor across the second period, the second delayed time being a time at which the EGR valve position crosses the other of the first and second diagnostic positions as adjusted by the exhaust gas transport delay time;after the second period, calculating a second actual range of measurement of the intake oxygen sensor, the second actual range of measurement being equal to a difference between the second maximum and minimum oxygen concentrations measured by the intake oxygen sensor during the second period; anddetecting a second sensor range malfunction of the intake oxygen sensor when the second actual range of measurement is less than the difference threshold indicative of the acceptable range of measurement by the intake oxygen sensor. 10. The diagnostic system of claim 6, wherein the controller is further configured to, during operation of the vehicle, verify each of: (i) no malfunctions of the EGR valve or the EGR valve position sensor; (ii) no circuit fault in the intake oxygen sensor or a heater associated therewith; and (iii) no communication issue between the intake oxygen sensor and the controller.
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이 특허에 인용된 특허 (3)
Sato, Fumihiko; Matsubara, Takuji; Yoshioka, Mamoru; Hyoudo, Yoshihiko; Takeuchi, Takayuki; Oyama, Naohisa; Daido, Shigeki, Combustible-gas sensor, diagnostic device for intake-oxygen concentration sensor, and air-fuel ratio control device for internal combustion engines.
Makki, Imad Hassan; Kerns, James Michael; Clark, Timothy Joseph; Jentz, Robert Roy; Uhrich, Michael James, Distinguishing between EGR valve and oxygen sensor degradation.
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