A method for a turbocharger of a heat engine including a turbine, a compressor, and a by-pass actuator that can be used to control an air flow that does not pass through the turbine. The method includes determining a position set point of the by-pass actuator as a function of a compression ratio set
A method for a turbocharger of a heat engine including a turbine, a compressor, and a by-pass actuator that can be used to control an air flow that does not pass through the turbine. The method includes determining a position set point of the by-pass actuator as a function of a compression ratio set point, a compression ratio measurement, a measurement of the rate of flow through the compressor, a measurement of the pressure downstream from the turbine, a measurement of the pressure downstream from the compressor, a measurement of the temperature upstream from the turbine, and a measurement of the temperature upstream from the compressor. The method can be used to control a supercharging device with a single or dual turbocharger.
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1. A method, for a turbocharger for supercharging a combustion engine including a turbine driven by exhaust gases, a compressor driven in rotation by the turbine so as to compress intake air, and a bypass actuator for bypassing the turbine, the method comprising: measuring, via at least one sensor o
1. A method, for a turbocharger for supercharging a combustion engine including a turbine driven by exhaust gases, a compressor driven in rotation by the turbine so as to compress intake air, and a bypass actuator for bypassing the turbine, the method comprising: measuring, via at least one sensor or estimator, a pressure downstream of the turbine, a pressure downstream of the compressor, a temperature upstream of the turbine, and a temperature upstream of the compressor;determining a compression ratio setpoint from a compressor map;measuring a compression ratio measurement across the compressor;determining an expansion ratio setpoint as a function of the compression ratio setpoint, of the compression ratio measurement, the pressure measurement downstream of the turbine, the pressure measurement downstream of the compressor, the temperature measurement upstream of the turbine, and the temperature measurement upstream of the compressor;determining a position setpoint for the bypass actuator as a function of the expansion ratio setpoint, and of a flowrate measurement of flowrate through the compressor; andactuating the bypass actuator to control an air flow rate of flow bypassing the turbine in response to the position setpoint as previously determined. 2. The method as claimed in claim 1, in which the determining of the position setpoint for the bypass actuator, as a function of the expansion ratio setpoint, uses an inverse actuator model. 3. The method as claimed in claim 2, in which the expansion ratio setpoint is, prior to use of the inverse actuator model, saturated as a function of a maximum authorized pressure downstream of the turbine, using formula: PRt,sp,sat=min(PRt,sp,Pdt,maxPdt), wherein PRt,sp,sat is the expansion ratio setpoint after saturation,PRt,sp is the expansion ratio setpoint before saturation,Pdt is the pressure downstream of the turbine,Pdt,max is the maximum acceptable pressure downstream of the turbine,the saturated compression ratio setpoint value thereafter replacing the initial compression ratio setpoint value. 4. The method as claimed in claim 2, in which the bypass actuator for bypassing the turbine is modeled by a Saint Venant equation, using formula Wact=SactPdtTdt·ψ(PR), wherein PR denotes the input parameter, namely, respectively: PRt,sp the expansion ratio setpoint,PRt,sp,ol the open-loop expansion ratio setpoint,PRt,sp,ol,sat the saturated open-loop expansion ratio setpoint,Wact is a flowrate through the actuator,Sact is a cross section of the actuator,Pdt is a pressure downstream of the turbine,Tdt is a temperature downstream of the turbine,Ψ is a function of the variable X, defined by ψ(X)=2γtR(γt-1)X-2γt-X-(γt-1)γt, wherein γt is a first thermodynamic constant of the exhaust gas, equal to 1.4,R is the universal gas constant, equal to 287 J/kg/K. 5. The method of determining as claimed in claim 4, in which the flowrate through the actuator is determined using formula Wact=Wc,m−Wt,sp, wherein Wc, m is a measurement of the flowrate through the compressor,Wt,sp is a flowrate setpoint for the flowrate through the turbine. 6. The method of determining as claimed in claim 4, in which the cross section of the actuator is mapped as a function of the position setpoint for the actuator and of the expansion ratio setpoint. 7. The method as claimed in claim 1, in which the expansion ratio setpoint is equal to the sum of an open-loop expansion ratio setpoint calculated as a function of the compression ratio setpoint by a first logic module, and of a closed-loop expansion ratio setpoint calculated as a function of an error between the compression ratio setpoint and the compression ratio measurement by a second logic module, wherein the first logic module is a prepositioning module, and the second logic module is a first controller module. 8. The method as claimed in claim 7, in which the prepositioning module comprises: determining a corrected flowrate measurement for the flowrate of intake air through the compressor as a function of a flowrate measurement for the flowrate of intake air through the compressor, using formula: Wc,m,cor=Wc,m·TucTc,ref·Pc,refPdc, wherein Wc, m,cor is the corrected flowrate measurement for the flowrate of intake air through the compressor,Wc,m is the air flowrate measurement for the flowrate of intake air through the compressor,Tuc is a temperature upstream of the compressor,Puc is a pressure upstream of the compressor,Tc,ref is a reference temperature of the compressor,Pc,ref is a reference pressure of the compressor;determining a corrected speed setpoint relative to the compressor, using a function of the compression ratio and of the corrected flowrate of intake air through the compressor, the function being defined by a two-dimensional map;determining a speed setpoint as a function of the corrected speed setpoint relative to the compressor, using formula: Nsp=Nsp,corcTucTc,ref, wherein Nsp is the speed setpoint of the turbocharger,Nsp,corc is the corrected speed setpoint relative to the compressor of the turbocharger,Tc is the temperature upstream of the compressor,Tc,ref is the reference temperature of the compressor;calculating an efficiency of the compressor as a function of the corrected speed setpoint relative to the compressor of the turbocharger and of the corrected air flowrate setpoint for the flowrate of intake air through the compressor, using a function of the corrected speed setpoint relative to the compressor of the turbocharger and of the corrected air flowrate setpoint for the flowrate of intake air through the compressor, the function being defined by a two-dimensional map;calculating a compressor power setpoint, using formula: Hc,sp=Wc,mCpc1ηcTuc(PRc,spγc-1γc-1), wherein Hc,sp is the power setpoint of the compressor,Wc,m is the air flowrate measurement for the flowrate of intake air through the compressor,ηc is the efficiency of the compressor,Tuc is the temperature upstream of the compressor,PRc,sp is the compression ratio setpoint of the compressor,Cpc is a first thermodynamic constant of the intake air,γc is a second thermodynamic constant of the intake air;calculating a turbine power setpoint using formula: Ht,sp=Hc,sp, whereinHt,sp is the power setpoint of the turbine,Hc,sp is the power setpoint of the compressor;determining a corrected speed setpoint relative to the turbine as a function of the speed setpoint, using formula: Nsp,cort=NspTt,refTut, wherein Nsp is the speed setpoint of the turbocharger,Nsp,cort is the corrected speed setpoint relative to the turbine of the turbocharger,Tut is a temperature upstream of the turbine,Tt,ref is a reference temperature of the turbine;calculating the open-loop expansion ratio setpoint, using formula: PRt,sp,ol=F-1(Hc,spCpt·Tut·PdtPt,ref·Tt,refTut,Nsp,cort), wherein PRt,sp,ol is the open-loop expansion ratio of the turbine,Ht,sp is the power setpoint of the turbine,Nsp,cort is the corrected speed setpoint relative to the turbine of the turbocharger, andF is a function defined by a two-dimensional map and obtained by inversion of the following equation: Ht,sp=Wt,sp·Cpt·ηt·Tut[1-(1PRt,sp,ol)γt-1γt], wherein Ht,sp is the power setpoint of the turbine,PRt,sp,ol is the open-loop expansion ratio of the turbine,Cpt is a first thermodynamic constant of the exhaust gas,γt is a second thermodynamic constant of the exhaust gas,ηt is an efficiency of the turbine that can be expressed by means of a function of the corrected speed setpoint relative to the turbine of the turbocharger and of the open-loop expansion ratio setpoint, the function being defined by a two-dimensional map,Wt,sp is a flowrate setpoint for the flowrate of exhaust gases through the turbine and determined by formula Wt,sp=Wt,sp,cor·Tt,refTut·PdtPt,ref, wherein Wt,sp is a flowrate setpoint for the flowrate of exhaust gases through the turbine,Wt,sp,cor is a corrected flowrate setpoint for the flowrate of exhaust gases through the turbine that can be expressed by a function of the corrected speed setpoint relative to the turbine of the turbocharger and of the open-loop expansion ratio setpoint, the function being defined by a two-dimensional map,Tut is a temperature upstream of the turbine,Tt,ref is a reference temperature of the turbine,Pdt is a pressure downstream of the turbine,Pt,ref is a reference pressure of the turbine. 9. The method as claimed in claim 7, in which the first controller module is a regulator configured to cancel the error. 10. The method as claimed in claim 9, in which the regulator uses fuzzy logic. 11. The method as claimed in claim 9, in which the regulator comprises a Proportional Integral Derivative module. 12. The method as claimed in claim 1, in which the position setpoint for the bypass actuator is equal to the sum of an open-loop position setpoint calculated as a function of the compression ratio setpoint, and of a closed-loop position setpoint calculated as a function of an error between the compression ratio setpoint and the compression ratio measurement by a second controller module. 13. The method as claimed in claim 12, in which the determining of the open-loop position setpoint comprises: determining an open-loop expansion ratio setpoint as a function of the compression ratio setpoint by a prepositioning module; anddetermining of an open-loop position setpoint as a function of the open-loop expansion ratio setpoint thus determined, using an inverse actuator model. 14. The method as claimed in claim 12, in which the position setpoint is finally saturated, using formula: αsp,sat=min(αsp,αsp,max), wherein αsp,sat is the position setpoint after saturation,αsp is the position setpoint before saturation,αsp,max is a maximum position setpoint. 15. The method as claimed in claim 14, in which the maximum position setpoint is determined as a function of the open-loop expansion ratio using an inverse actuator model. 16. The method as claimed in claim 15, in which the open-loop expansion ratio setpoint is, prior to application of the inverse actuator model for determining the maximum position setpoint αsp,max, saturated as a function of a maximum authorized pressure downstream of the turbine, using formula: PRt,sp,sat=min(PRt,sp,ol,Pdt,maxPdt), wherein PRt,sp,sat is the expansion ratio setpoint after saturation,PRt,sp,ol is the expansion ratio setpoint before saturation,Pdt is the pressure downstream of the turbine,Pdt,max is the maximum acceptable pressure downstream of the turbine,the saturated expansion ratio setpoint value thereafter replacing the initial open-loop expansion ratio setpoint value. 17. A method, for a fixed geometry double supercharging device for supercharging a combustion engine, comprising: a high-pressure first turbocharger comprising a high-pressure turbine driven by the exhaust gases emanating from the combustion engine, a high-pressure compressor driven in rotation by the high-pressure turbine so as to compress the intake air injected into the combustion engine, and a high-pressure bypass actuator for bypassing the high-pressure turbine making it possible to command an air flowrate that does not pass through the high-pressure turbine;a low-pressure second turbocharger comprising a low-pressure turbine driven by the exhaust gases emanating from the combustion engine via the high-pressure turbine or the high-pressure bypass actuator, a low-pressure compressor driven in rotation by the low-pressure turbine so as to compress the intake air injected into the combustion engine via the high-pressure compressor, and a low-pressure bypass actuator for bypassing the low-pressure turbine making it possible to command an air flowrate that does not pass through the low-pressure turbine; anda bypass valve for the high-pressure compressor allowing the high-pressure compressor to be selectively bypassed so as to connect the low-pressure compressor directly to the engine,the method comprising for both the high-pressure turbocharger and the low-pressure turbocharger:measuring a pressure downstream of each turbine, a pressure downstream of each compressor, a temperature upstream of each turbine, and a temperature upstream of each compressor via at least one sensor or estimator;determining a compression ratio setpoint from a compressor map;measuring a compression ratio measurement across the compressor;determining an expansion ratio setpoint as a function of the compression ratio setpoint, the compression ratio measurement, the pressure measurement downstream of each turbine, the pressure measurement downstream of each compressor, the temperature measurement upstream of each turbine, and the temperature measurement upstream of each compressor;determining a position setpoint for each bypass actuator as a function of each expansion ratio setpoint, and of a flowrate measurement of flowrate through each compressor;selecting, by a handler, which bypass actuator out of the high-pressure bypass actuator and the low-pressure bypass actuator to command;accordingly selecting the position setpoint for the high-pressure bypass actuator or the position setpoint for the low-pressure bypass actuator; andactuating the selected bypass actuator in response to the selected position setpoint. 18. The method as claimed in claim 17, in which the selecting is carried out by the handler in accordance with the following rules: the high-pressure bypass actuator is operated when the speed of the engine is below a threshold, the bypass valve of the high-pressure compressor being forced closed and the low-pressure bypass actuator being forced closed; andthe low-pressure bypass actuator is operated when the speed of the engine is above a threshold, the bypass valve of the high-pressure compressor being forced open and the high-pressure bypass actuator being forced open. 19. The method as claimed in claim 18, in which the threshold speed for the engine is equal to 2750 rpm.
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