Method to control a burner for an exhaust system of an internal combustion engine

The invention claimed is: 1. A method to control an internal combustion engine ( 1 ) provided with a mass flow sensor ( 9 ; 39 ) and with an exhaust system ( 2 ) for the exhaust gases of a motor vehicle having an exhaust duct ( 10 ) and an exhaust gas after-treatment system ( 14 ) comprising at least one catalytic converter ( 15 , 17 ) arranged along the exhaust duct ( 10 ); a burner ( 21 ), which is suited to introduce exhaust gases into the exhaust duct ( 10 ) so as to speed up a heating of said at least one catalytic converter ( 15 , 17 ), wherein inside the burner ( 21 ) there is defined a combustion chamber ( 22 ), which receives fuel from an injector ( 27 ), which is designed to inject fuel into the combustion chamber ( 22 ), and fresh air through an air feeding device ( 23 ), which is provided with a pumping device ( 24 ) feeding air, and with a shut-off valve ( 26 ) arranged upstream of the burner ( 21 ); the method comprises the following steps: calculating a thermal power (P OBJ ) needed to reach a nominal operating temperature of said at least one catalytic converter ( 15 , 17 ); determining an objective air flow rate ({dot over (m)} A_OBJ ) to be fed to the burner ( 21 ) in order to obtain said thermal power (P OBJ ) needed to reach the nominal operating temperature of said at least one catalytic converter ( 15 , 17 ); determining a nominal number (N NOM ) of revolutions with which to operate the pumping device ( 24 ) by means of a map depending on the objective air flow rate ({dot over (m)} A_OBJ ), on an ambient pressure (P ATM ), on an ambient temperature (T ATM ) and on a pressure (P A ) of the air flowing into the burner ( 21 ); determining a closed-loop contribution (N CL ) of the number of revolutions with which to operate the pumping device ( 24 ) by means of a PID controller, which zeroes a difference between the objective air flow rate ({dot over (m)} A_OBJ ) and an air flow rate ({dot over (m)} A ) determined through the mass flow sensor ( 9 ; 39 ); determining a further contribution (N ADAT ) of the number of revolutions with which to operate the pumping device ( 24 ) depending on an integral action of the PID controller under stationary conditions; determining an actual number (N) of revolutions with which to operate the pumping device ( 24 ) by means of a sum of the nominal number (N NOM ) of revolutions, of the closed-loop contribution (N CL ) of the number of revolutions with which to operate the pumping device ( 24 ) and of the further contribution (N ADAT ) of the number of revolutions with which to operate the pumping device ( 24 ); and operating the pumping device ( 24 ) according to the actual number (N) of revolutions. 2. The method according to claim 1 , wherein the mass flow sensor ( 9 ) is housed along an intake duct ( 6 ) feeding fresh air to the internal combustion engine ( 1 ) and to the burner ( 21 ). 3. The method according to claim 2 comprising the further step of calculating an air flow rate ({dot over (m)} A ) by subtracting an air flow ({dot over (m)} ICE ) fed to the internal combustion engine ( 1 ) from a total air flow rate ({dot over (m)} TOT ) detected by the mass flow sensor ( 9 ). 4. The method according to claim 1 , wherein the mass flow sensor ( 39 ) is housed along a first duct ( 25 ), interposed between the pumping device ( 24 ) and the shut-off valve ( 26 ). 5. The method according to claim 1 , wherein the mass flow sensor is housed along a first duct ( 25 ), upstream of the pumping device ( 24 ). 6. The method according to claim 1 comprising the further step of signalling a fault when a sum of the closed-loop contribution (N CL ) of the number of revolutions and of the further contribution (N ADAT ) of the number of revolutions with which to operate the pumping device ( 24 ) exceeds a predetermined threshold value (THR 1 ). 7. The method according to claim 1 comprising the further step of determining a nominal fuel flow rate ({dot over (m)} FUEL_N ) to be fed to the burner ( 21 ) by means of the following formula: m . FUEL - N = m . A ( A F STEC * λ OBJ ) {dot over (m)} FUEL-N nominal fuel flow rate; {dot over (m)} A flow rate measured with the mass air flow sensor ( 9 ; 39 ); A/F STEC stoichiometric air and fuel ratio; A OBJ objective value of an air/fuel ratio. 8. The method according to claim 7 comprising the further steps of: determining a closed-loop contribution ({dot over (m)} F_CL ) of a fuel flow rate by means of the PID controller, which zeroes a difference between an objective value (λ OBJ ) of the air/fuel ratio and an actual value ( 2 ) of the air/fuel ratio measured by an oxygen sensor ( 18 , 18 *, 18 **); determining a further contribution ({dot over (m)} F_ADAT ) of the fuel flow rate depending on the integral action of the PID controller under stationary conditions; and determining an objective fuel flow rate ({dot over (m)} F_OBJ ) by means of a sum of the nominal fuel flow rate ({dot over (m)} FUEL_N ), of the closed-loop contribution ({dot over (m)} F_CL ) of the fuel flow rate and of the further contribution ({dot over (m)} F_ADAT ) of the fuel flow rate. 9. The method according to claim 8 comprising the further step of signalling a fault when a sum of the closed-loop contribution ({dot over (m)} F_CL ) and of the further contribution ({dot over (m)} F_ADAT ) of the fuel flow rate exceeds a predetermined threshold value. 10. The method according to claim 1 , wherein, in a case of a fault of the mass flow sensor ( 9 ; 39 ), the air flow rate ({dot over (m)} A ) is calculated by means of a map depending on the ambient pressure (P ATM ), on the ambient temperature (T ATM ), on the pressure (P A ) of the air flowing into the burner ( 21 ), on the actual number (N) of revolutions with which to operate the pumping device ( 24 ) and on the further contribution (N ADAT ) of the number of revolutions with which to operate the pumping device ( 24 ).