FR3050767B1 - METHOD OF CONTROLLING INJECTION CUTOFF AT THERMAL MOTOR STOP - Google Patents

Abstract

The invention relates mainly to a method of controlling an injection cut-off (C_Inj) during a thermal engine shutdown, characterized in that, following a request to stop said heat engine, said method comprises: step of determining an injection cut-off time (C_Inj) from taking into account the following parameters: a coolant temperature (water), an atmospheric pressure (Patmo), a dispersion, and a drift time of an air metering device, and - an injection cutting step (C_Inj) following an expiration of said injection cut-off time (C_Inj) previously determined.

Description

METHOD OF CONTROLLING INJECTION CUTOFF AT THERMAL MOTOR STOP

The present invention relates to a method of controlling an injection cutoff during a thermal engine shutdown. The invention finds a particularly advantageous application in the management of the stopping control of a thermal engine, particularly diesel type, fitted to a motor vehicle equipped with a system for stopping and automatic restart of the engine or STT system ( "Stop and Start" in English).

For a powertrain equipped with an STT system, during the driving cycle, the engine of the vehicle can be frequently stopped temporarily for the purpose of minimizing fuel consumption. These temporary stops can be very numerous.

To manage these stops and starts, it is expected to associate the engine with a control supervisor which determines, according to the different queries for stopping the engine from the different functions of the control command, a cutoff instruction injection of the engine.

The shutdown of the engine covers the following two phases of life: the stopping phase called STT bringing the engine at a zero speed under the "Stop and Start" function, and the key break phase bringing the heat engine to a zero speed by cutting the power supply of the engine by the key or the start button.

As shown in Figure 1, following a request to stop the engine De at time t1, there is a delay time T during which the air doser Pdos is gradually closed. At the end of the delay time T, the injection is cut C_lnj at time t2. Stopping the operation of the engine occurs at time t3, while the engine speed Wm gradually decreases throughout the engine stopping phase to become zero at time t4.

It was observed a significant dispersion of the stop benefit depending on the operating conditions, and a dispersion between the vehicles, and a degradation of the service during the aging of the vehicle.

The invention aims to effectively overcome these disadvantages by providing a method of controlling an injection cutoff during a thermal engine shutdown characterized in that, following a stop request of the engine, the method comprises: a step of determining an injection cutoff time from taking into account the following parameters: a coolant temperature, an atmospheric pressure, a dispersion, and a time drift of an air metering device, and - an injection cutting step following an expiration of the previously determined injection cutoff time.

The invention thus makes it possible to adapt the injection cut-off as a function of the dynamics of the engine, of the air metering device, and of thermodynamic parameters which have an influence on the shutdown performance of the engine. The invention also makes it possible to select an injection cutoff time optimizing the compromise between the stopping speed of the engine and the feeling of stopping.

According to one embodiment, taking into account the temperature of the engine and the atmospheric pressure is performed via the implementation of a mapping returning a threshold time compared with a time elapsed since a stop request of the engine. This makes it possible to adapt the injection cut-off according to the dynamics of the engine, that of the metering device, and the air line that can vary according to the temperature of the engine.

According to one embodiment, the taking into account of the dispersion, and of the time drift of the air metering unit is carried out via the implementation of a mapping returning a threshold position of the air metering device compared with a actual position of the air metering unit.

According to one embodiment, the taking into account of the atmospheric pressure is performed via the implementation of a mapping returning a threshold depression on admission compared with a real depression on admission.

According to one embodiment, the method comprises a step of adding a maximum calibratable time delay before cutting the injection, in case of malfunction of the air metering device.

According to one embodiment, the maximum calibratable time delay is of the order of 300 milliseconds.

According to one embodiment, the method comprises a step of pre-positioning the air metering device before starting a stopping phase of the engine. Thus, by at least partially closing the air metering device, for example at 50% of the total closure, this reduces the engine stopping time and improves the feeling of the driver.

According to one embodiment, the method comprises a step of controlling an exhaust gas recirculation system or a turbocharger during the stopping phase of the heat engine. Thus, by allowing a flow of certain gases in the engine, such a control makes it possible to obtain a pressure balance between the combustion chambers.

According to one embodiment, control law calibrations are different for a stop phase of the engine controlled by a stop system and automatic restart of the engine or a stop phase type key cutoff .

The invention also relates to a control system comprising a memory storing instructions for the implementation of the control method as defined above.

The invention will be better understood on reading the description which follows and the examination of the figures that accompany it. These figures are given for illustrative but not limiting of the invention.

Figure 1, already described, is a timing diagram illustrating a stopping phase of the engine during the implementation of a control method of the prior art; Figure 2 is a schematic functional representation of the various modules implementing the control method of an injection cutoff according to the present invention.

FIG. 2 is a diagrammatic representation of the logic modules 10 to 15 making it possible, following a request to stop the heat engine, to determine the injection cut-off time C_lnj from taking into account the following parameters. : a water coolant temperature, a Patmo atmospheric pressure, a dispersion, and a time drift of an air metering device.

According to a first type of injection cut T_ci, a map C_Temp provides a threshold duration ts injection cutoff as a function of the water coolant temperature and atmospheric pressure Patmo. A module 10 then compares the threshold duration ts returned by the map C_Temp with a time elapsed t_Arr from a request to stop the engine. The module 10 will change its output state (which may for example go to the state 1 or 0 according to its initial binary state) when the elapsed time t_Arr will reach the threshold duration ts, and the injection cutoff C_lnj can then to be allowed.

Mapping C_Temp and adapts the injection cut-off according to the dynamics of the engine, the metering device, and the air line may vary depending on the engine temperature. In addition, the C_Temp cartography makes it possible to take into account the atmospheric pressure Patmo varying the stopping conditions when one is at high altitude. Indeed, the thermodynamic conditions of the combustion chamber are very different for a zero altitude compared to a high altitude, 2000 meters for example.

According to a second type of injection cut T_ci, mapping C_Fdos provides a closing threshold position Ready air metering, called reference. A module 11 then compares the ready threshold position returned by the map C_Fdos with a measured actual position of the air metering heads. The module 11 will change its output state (which may, for example, change to the state 1 or 0 depending on its initial binary state) when the actual position of the air metering heads will reach the set threshold position, and the cutoff of injection C_lnj can then be allowed. The cartography C_Fdos thus makes it possible to take into account the dispersion and the time drift of the air metering device.

According to a third type of T_ci injection cutoff, a C_Dad mapping provides a threshold depression at the Dref admission, referred to as reference. A module 12 then compares the threshold depression D ref returned by the map C_Dad with a real depression measured at the admission Dmes. The module 12 will change its output state (which may for example go to state 1 or 0 depending on its initial binary state) when the actual negative pressure at the intake D mes will reach the threshold depression D ref, and the cutoff injection C_lnj can then be allowed.

A selector 14 allows to select, depending on the life situation of the motor vehicle, the type of injection cut T_ci to apply. Alternatively, the different types of injection cut T_ci can be combined with each other, and if necessary prioritize, depending on the vehicle's life situation.

In case of malfunction of the air metering device, mapping C_Del provides a maximum calibratable time delay tmax before injection cut C_lnj. A module 13 then compares the maximum delay tmax returned by the mapping C_Del with the elapsed time t_Arr from a stop request of the engine. The module 13 will change its output state (which may for example go to state 1 or 0 depending on its initial binary state) when the elapsed time t_Arr will reach the maximum delay tmax, and the injection cutoff C_lnj can then to be allowed. The output of the module 13 may be connected to the input of a logic gate 15, of the OR type, in parallel with the output of the selector 14. The maximum delay tmax may for example be of the order of 300 milliseconds.

In the case of a stop phase controlled by a stop system and automatic restart of the engine (STT type) or a key-off type of stop phase, the same architecture is used. logic of the control system, but the calibrations of the control laws are different. The threshold values ts, Pref, Dref, and tmax may thus be different from one type of stopping phase (STT or key type) to another.

In some advanced implementations, before starting the stopping phase of the engine, the air metering can be pre-positioned. Thus, by at least partially closing the air metering device, for example at 50% of the total closure, this reduces the engine stopping time and improves the feeling of the driver.

It will also be possible to provide control of an exhaust gas recirculation system or a turbocharger during the stopping phase of the engine. Thus, by allowing a circulation of certain gases in the heat engine, such a control makes it possible to obtain a pressure balance between the combustion chambers, which also improves the feeling of the driver and reduces the stopping time of the engine. .

The control laws as well as the logic modules 10 to 15 may be implemented in a control system comprising a memory storing instructions for the implementation of the control method described above. This control system may be separate or confused with the engine computer.

Claims (9)

Claims: 1. A method of controlling an injection cut-off (C_lnj) during a thermal engine shutdown, characterized in that, following a request to stop said heat engine, said method comprises: a determination step of an injection cut-off time (CJnj) from taking into account the following parameters: a coolant temperature (water), an atmospheric pressure (Patmo), a dispersion, and a time drift of a metering device of air, and - an injection cutting step (C_lnj) following an expiration of said injection cut-off time (CJnj) previously determined, and in that the taking into account of said temperature of the heat engine (water) and said atmospheric pressure (Patmo) is performed via the implementation of a map (C_Temp) returning a threshold duration (ts) compared with an elapsed time (t_Arr) from a request to stop said heat engine. 2. Method according to claim 1, characterized in that the taking into account of said dispersion, and said time drift of the air metering device is performed via the implementation of a mapping (C_Fdos) returning a threshold position (Pref ) of said air metering device compared with a real position (Pmes) of said air metering device. 3. Method according to any one of claims 1 or 2, characterized in that the taking into account of said atmospheric pressure (Patmo) is performed via the implementation of a mapping (C_Dad) returning a threshold depression (D_ref) at admission compared with a real depression (Dmes) at admission. 4. Method according to any one of the preceding claims, characterized in that it comprises a step of adding a maximum calibratable time delay (tmax) before cutting the injection, in case of malfunction of said air metering device. 5. Method according to the preceding claim, characterized in that said maximum calibratable time delay (tmax) is of the order of 300 milliseconds. 6. Method according to any one of the preceding claims, characterized in that it comprises a step of pre-positioning said air metering before starting a stopping phase of said engine. 7. Method according to any one of the preceding claims, characterized in that it comprises a step of controlling an exhaust gas recirculation system or a turbocharger during said stopping phase of said engine. 8. Method according to any one of the preceding claims, characterized in that calibrations of control laws are different for a stop phase of said engine controlled by a stop system and automatic restart of the engine or a phase stop type key break. 9. Control system comprising a memory storing instructions for implementing the control method as defined in any one of the preceding claims.