An apparatus includes an operating conditions module that interprets a number of compressor operating parameters; a compressor flow module that determines a compressor inlet flow in response to the number of compressor operating parameters; and a fresh air flow module that provides a fresh air flow
An apparatus includes an operating conditions module that interprets a number of compressor operating parameters; a compressor flow module that determines a compressor inlet flow in response to the number of compressor operating parameters; and a fresh air flow module that provides a fresh air flow value in response to the compressor inlet flow. The operating conditions module further interprets a current mass air flow value, and the apparatus further includes a mass air flow sensor trimming module that adjusts a mass air flow sensor drift value in response to the current mass air flow value and the fresh air flow value. The apparatus includes a diagnostics module that determines a mass air flow sensor is failed in response to the current mass air flow value and the fresh air flow value.
대표청구항▼
1. A method comprising: interpreting a plurality of compressor operating parameters of a compressor of a turbocharger during operation of an internal combustion engine system;determining a compressor inlet flow value in response to the plurality of compressor operating parameters;determining an esti
1. A method comprising: interpreting a plurality of compressor operating parameters of a compressor of a turbocharger during operation of an internal combustion engine system;determining a compressor inlet flow value in response to the plurality of compressor operating parameters;determining an estimate of a fresh air flow value to the internal combustion engine from the compressor inlet flow value; andcorrecting a drift value of a mass air flow sensor upstream of the compressor in response to a current mass air flow value measured by the mass air flow sensor and the estimate of the fresh air flow value. 2. The method of claim 1, further including adjusting a mass air flow sensor drift value in response to the current mass air flow value and the estimate of the fresh air flow value. 3. The method of claim 1, further including determining a mass air flow sensor status in response to the current mass air flow value and the estimate of the fresh air flow value. 4. The method of claim 1, further including interpreting a regression model of a compressor and determining the compressor inlet flow value in response to the regression model of the compressor and one of a compressor outlet pressure value and a charge pressure value. 5. The method of claim 1, further including: providing a compressor outlet pressure value;interpreting a compressor map and the compressor outlet pressure value; anddetermining the compressor inlet flow value in response to the compressor map and the compressor outlet pressure value. 6. The method of claim 5, further including interpreting a compressor map reliability value in response to an operating location on the compressor map and determining the compressor inlet flow value in response to the compressor map reliability value exceeding a reliability threshold value. 7. The method of claim 5, wherein the compressor map further includes a high reliability region, the method further including interpreting whether a compressor is operating in the high reliability region and determining the compressor inlet flow value in response to the compressor operating in the high reliability region. 8. The method of claim 1, wherein the determining the compressor inlet flow value comprises operating a physics based compressor model. 9. The method of claim 8, wherein the operating the physics based compressor model includes considering a mass conservation term, a momentum conservation term, a turbocharger torque balance term, and a compressor thermodynamic efficiency term. 10. The method of claim 8, further including interpreting an engine steady state condition and determining the compressor inlet flow value in response to the engine steady state condition. 11. The method of claim 10, further comprising interpreting a response time of a sensor, and interpreting the engine steady state condition in response to the response time of the sensor. 12. An apparatus comprising: a controller with a memory and a plurality of modules configured to execute operations of the controller, wherein the controller is configured to receive a plurality of operating parameters from an engine system including a turbocharger with a compressor, the plurality of modules including: an operating conditions module structured to interpret a plurality of compressor operating parameters and a current mass air flow value from a mass air flow sensor upstream of the compressor during operation of the engine system;a compressor flow module structured to determine a compressor inlet flow value to the compressor in response to the plurality of compressor operating parameters; anda fresh air flow module structured to determine an estimate of a fresh air flow value to the engine system from the compressor inlet flow value, wherein the controller is configured to correct a drift value of the mass air flow sensor in response to the current mass air flow value and the estimate of the fresh air flow value. 13. The apparatus of claim 12, wherein the controller further comprises a mass air flow sensor trimming module structured to adjust a mass air flow sensor drift value in response to the current mass air flow value and the estimate of the fresh air flow value. 14. The apparatus of claim 12, wherein the controller further comprises a diagnostics module structured to determine a mass air flow sensor is failed in response to the current mass air flow value and the estimate of the fresh air flow value. 15. The apparatus of claim 12, wherein the operating conditions module is further structured to interpret a regression model of the compressor and wherein the compressor flow module is further structured to determine the compressor inlet flow value in response to the regression model of the compressor and one of a compressor outlet pressure value and a charge pressure value. 16. The apparatus of claim 12, wherein the operating conditions module is further structured to interpret a compressor map and a compressor outlet pressure value, and wherein the compressor flow module is further structured to determine the compressor inlet flow value in response to the compressor map and the compressor outlet pressure value. 17. The apparatus of claim 16, wherein the controller comprises a compressor map noise module structured to interpret a compressor map reliability value in response to an operating location on the compressor map, and wherein the compressor flow module is further structured to determine the compressor inlet flow value in response to the compressor map reliability value exceeding a reliability threshold value. 18. The apparatus of claim 16, wherein the compressor map further includes a high reliability region, the controller further comprises a compressor map noise module structured to interpret whether a compressor is operating in the high reliability region, and wherein the compressor flow module is further structured to determine the compressor inlet flow value in response to the compressor operating in the high reliability region. 19. The apparatus of claim 12, wherein the compressor flow module is further structured to determine the compressor inlet flow value by operating a physics based compressor model. 20. The apparatus of claim 19, wherein the physics based compressor model includes a mass conservation consideration, a momentum conservation consideration, a turbocharger torque balance consideration, and a compressor thermodynamic efficiency consideration. 21. The apparatus of claim 20, wherein the operating conditions module is further structured to interpret a compressor outlet pressure value and a compressor outlet temperature value, and wherein the compressor flow module is further structured to determine the compressor inlet flow value in response to the compressor outlet pressure value and the compressor outlet temperature value. 22. The apparatus of claim 21, wherein the compressor flow module is further structured to determine the compressor inlet flow value utilizing a plurality of equations comprising: m.=ρ1v1A1=ρ2v2A2;v2=P1P2A1A2T2T1v1;ρ2A2Rv22=RA2P2+τcomp;τcomp·ω=m.·Cp·T01ηcomp·(1-(P02P01)γ-1γ);ηcomp=(P02P01)γ-1γ-1T02T01-1;T01=T1+v122Cp;P01=P1(T01T1)γγ-1;T02=T2+v222Cp;P02=P2(T02T2)γγ-1;wherein {dot over (m)} comprises the compressor inlet flow value, ρ1 ρ2 comprise a first and second density value, ν1 and ν2 comprise inlet and outlet velocity values, A1 and A2 comprise inlet and outlet area values, P1 and P01 comprise the normal and stagnation compressor inlet pressure values, P2 and P02 comprise the normal and stagnation compressor outlet pressure values, T1 and T01 comprise the normal and stagnation compressor inlet temperature values, T2 and T02 comprise the normal and stagnation compressor outlet temperature values, R comprises a gas constant, τcomp comprises a compressor torque value, ω comprises a compressor rotational speed, Cp comprises a specific heat capacity of the compressor gases, ηcomp comprises a compressor efficiency value, and wherein γ comprises a specific heat ratio. 23. A system comprising: an engine;a turbocharger having a compressor and a turbine;a mass air flow sensor upstream of the compressor operable to measure a current mass air flow value;a controller comprising: an operating conditions module structured to interpret a plurality of compressor operating parameters and the current mass air flow value;a compressor flow module structured to determine a compressor inlet flow value in response to the plurality of compressor operating parameters; anda fresh air flow module structure to determine an estimate of a fresh air flow value from the compressor inlet flow value, wherein the controller is configured to correct a drift value of the mass air flow sensor in response to the current mass air flow value and the estimate of the fresh air flow value. 24. The system of claim 23, wherein the controller further comprises a mass air flow sensor trimming module structured to adjust a mass air flow sensor drift value in response to the current mass air flow value and the estimate of the fresh air flow value. 25. The system of claim 23, wherein the controller further comprises a diagnostics module structured to determine the mass air flow sensor is failed in response to the current mass air flow value and the estimate of the fresh air flow value. 26. The system of claim 23, wherein the operating conditions module is further structured to interpret a regression model of the compressor and wherein the compressor flow module is further structured to determine the compressor inlet flow value in response to the regression model of the compressor and one of a compressor outlet pressure value and a charge pressure value. 27. The system of claim 23, further including a compressor outlet pressure sensor providing a compressor outlet pressure value, wherein the operating conditions module is further structured to interpret a compressor map and the compressor outlet pressure value, and wherein the compressor flow module is further structured to determine the compressor inlet flow value in response to the compressor map and the compressor outlet pressure value. 28. The system of claim 27, wherein the controller further comprises a compressor map noise module structured to interpret a compressor map reliability value in response to a current operating location on the compressor map, and wherein the compressor flow module is further structured to determine the compressor inlet flow value in response to the compressor map reliability value exceeding a reliability threshold value. 29. The system of claim 27, wherein the compressor map further includes a high reliability region, wherein the controller further comprises a compressor map noise module structured to interpret whether the compressor is operating in the high reliability region, and wherein the compressor flow module is further structured to determine the compressor inlet flow value in response to the compressor operating in the high reliability region. 30. The system of claim 23, wherein the compressor flow module is further structured to determine the compressor inlet flow value by operating a physics based compressor model. 31. The system of claim 30, wherein the physics based compressor model includes a mass conservation consideration, a momentum conservation consideration, a turbocharger torque balance consideration, and a compressor thermodynamic efficiency consideration. 32. The system of claim 31, further comprising a compressor outlet pressure sensor providing a compressor outlet pressure value and a compressor outlet temperature sensor providing a compressor outlet temperature value, wherein the operating conditions module is further structured to interpret the compressor outlet pressure value and the compressor outlet temperature value, and wherein the compressor flow module is further structured to determine the compressor inlet flow value in response to the compressor outlet pressure value and the compressor outlet temperature value. 33. The system of claim 30, wherein the operating conditions module is further structured to interpret an engine steady state condition and wherein the compressor flow module is further structured to determine the compressor inlet flow value in response to the engine steady state condition. 34. The system of claim 33, wherein the controller further comprises a steady state determination module structured to determine whether the engine is in a steady state condition in response to a response time of a sensor in the system.
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