WO2013068670A1 - Method for controlling the fuel supply to an internal combustion engine equipping a motor vehicle - Google Patents

Abstract

The invention relates to a method for controlling the fuel supply to an internal combustion engine (1) equipping a motor vehicle. The control method comprises a step for calculating a quantity (Q) of fuel to be injected by an injector (3) into a respective cylinder (2). The calculation step is dependent upon information relating to a torque (C) of the internal combustion engine (1). The control method comprises a step of injecting the quantity (Q) of fuel into the corresponding cylinder (2) at an injection pressure (Prail). The calculation step is dependent upon information (INF) relating to an activation status E of a brake (12).

Description

 METHOD FOR CONTROLLING A FUEL SUPPLY OF AN INTERNAL COMBUSTION ENGINE EQUIPPED WITH A MOTOR VEHICLE

The invention relates to the field of control methods and devices for a fuel supply of an internal combustion engine. It relates to a method of securing the control of a fuel supply of an internal combustion engine fitted to a motor vehicle. It also relates to a device for implementing such a method. [Ooo2] An internal combustion engine equipping a motor vehicle includes injectors that are able to deliver a given amount of fuel within respective cylinders that includes the internal combustion engine. In the case where the internal combustion engine is a diesel engine, such an injection is commonly carried out by means of said injectors which are jointly fueled by means of a common rail, so called according to the English terminology. Saxon common rail. The motor vehicle is equipped with a computer to implement a control method so that a given injection (or a given injection time) is operated depending eg on the engine speed and the driving state of the accelerator pedal.

[ooo3] However, if an element of the computer is faulty, there is a risk of ordering too much injection which will cause an untimely acceleration of the vehicle. In the remainder of this document, we will describe as untimely acceleration an acceleration higher than equal to 1, 5 m. s ^"2 (assuming no acceleration is requested, or greater than the requested acceleration by more than 1.5 m. s ^{" 2} .

[ooo4] It is certainly possible to minimize this risk by redundant equipment, but this has a very important cost. In the automotive industry, the practice is therefore to double the calculation function with basic monitoring. A surveillance strategy commonly implemented is the so-called "zero torque" or "zero torque" strategy. It is based on the assumption that during a survey of the driver's foot, so in the absence of a request for acceleration, we must not observe fuel injection. This strategy is simple to implement and advantageously does not require knowledge of the injection pressure (pressure in the common rail injection). On the other hand, it supposes that indeed, no injection is commanded during these phases of foot-lift. However, with modern engine control methods, these foot-lift phases are often used for operations such as, for example, the registration of injectors or post-injections associated with regeneration strategies for the depollution elements present in the line. 'exhaust.

[ooo6] Another surveillance strategy is called continuous torque, according to the Anglo-Saxon terminology "continuous torque". This strategy is based on an elementary mapping which, at a given engine speed and a given acceleration request (eg translation of the depression state of the accelerator pedal), will associate a maximum torque possible, any value of torque greater than this maximum torque being considered as an indication of a failure of the injection system. This permanent check of the motor torque continuity can only be used if there is indeed a torque demand and moreover, for engines powered by a common rail, assumes that the pressure information in this rail (Prail) is known exactly, but this information is not secure.

[Ooo7] The document EP 1, 388,661 describes a control method, said strategy of resetting the injector which is intended to be applied in the case where the motor vehicle undergoes a constant deceleration phase. This injector resetting strategy includes a step of determining a nominal activation time (EN) of the injector involved in said injection as a function of the injection pressure (Prail) and a nominal amount of fuel. required (Qi). It also includes a step of determining a correction activation time (ET) as a function of the injection pressure (Prail) and the cylinder involved in the injection. This control method also comprises a step of determining, in the case where the required nominal fuel quantity (Qi) is less than a predetermined threshold (SQ), a corrected activation time (EC) by correcting said time nominal activation according to said correction activation time (ET).

[0oo9] This method finally comprises a step of exciting said injector for a time equal to said corrected activation time (EC).

[ooi o] Said step of determining said correction activation time (ET) comprises the steps of: · performing, in the presence of a predetermined series of operating conditions of the internal combustion engine, a succession of activations of said activation time injector gradually increasing,

Determining an amount (Acc) relating to an output torque of the internal combustion engine in response to said succession of activations,

Calculating the correction activation time (ET) according to said quantity (Acc) relating to the output torque.

[ooi i] However, this injector recalibration strategy is incompatible as it is with the "0 torque" strategy. There is therefore a need for a process that can be implemented under various deceleration conditions and / or in phases where the output torque of the internal combustion engine is zero, to make the operation of the engine at maximum internal combustion and to avoid an unpleasant feeling for a user of the motor vehicle, type of untimely acceleration generated in response to the observed deceleration.

[Ooi 2] An object of the present invention is to provide a variant of the so-called zero torque strategy compatible with a registration of the injectors and independent of the error that may exist on the value of the rail pressure.

This object is achieved by a method of monitoring a fuel supply system of an internal combustion engine (1), said system comprising at least two injector (3) for injecting a quantity (Q) of fuel into a cylinder, said injectors being fed by a common rail, according to which, in the periods during which no torque request is made, it is checked whether a request for recalibration of the injectors is active, and if this is not the case, it is checked whether the quantity of fuel injected is then zero, or in the case of a request for registration of the injectors active, an injection of fuel only during a time limit such that the injection associated with the registration does not produce an inadvertent acceleration.

As indicated above, an acceleration will typically be considered untimely when its value is greater than 1, 5 ms ^"2 , This limit can be changed depending on the presumed sensitivity of the driver (and on a sporty typed vehicle, the customer is often more able to locate an uncontrolled acceleration, we can then choose to lower this threshold a bit. [0015] The limit time is calculated assuming that the pressure in the common rail is equal to its limit pressure for which the system is designed.

Thus, we can secure the maximum operation of the engine, and that of the vehicle that is equipped, and ensure that it will not occur lurching of the vehicle due to untimely acceleration, while allowing to perform a registration of the injectors in a manner essentially not perceptible by the driver or the occupants of the vehicle.

[Ooi 7] Advantageously, this monitoring method does not require new sensors or redundancy of some computers or sensors, and is independent of the reliability of the information on the pressure in the common rail. The present invention relates to a method for verifying the control of an injector in a so-called "0 torque"situation; applied to the fuel supply of an internal combustion engine fitted to a motor vehicle. This method of checking the control comprises a step of calculating a maximum value of the quantity of fuel to be injected by an injector into a respective cylinder so as not to cause inadvertent acceleration. The invention tests whether the injected fuel quantity value is zero when the injector reset function is inactive and that this injected fuel value is less than a threshold calculated according to the maximum error on Prail and ensuring compliance with the inadvertent acceleration. According to a variant of the present invention, the calculation step is dependent on information relating to an activation state of a brake.

According to a first case in which the torque is zero and the information relating to the activation state consists of a first information relating to a first state in which a pressure on the brake is found, the quantity is calculated according to a corrected opening time of the injector and a maximum injection pressure.

According to a second case in which the torque is zero and the information relating to the activation state consists of a second information relating to a second state according to which the brake is not pressed, the quantity is calculated according to a nominal opening time of the injector and the injection pressure.

A control device of the present invention is a control device for the implementation of such a control method which is mainly recognizable in that the control device comprises a computer equipped with a force sensor equipping the brake.

The control device advantageously comprises a torque sensor fitted to the internal combustion engine.

The control device advantageously comprises a pressure sensor equipping a common rail equipping the internal combustion engine. [0026] A motor vehicle of the present invention is equipped with an internal combustion engine provided with such a control device.

Other features and advantages of the present invention will appear on reading the description which will be made of embodiments, in connection with the figures of the attached plates, in which: • Figure 1 is a schematic view of a fuel supply control device according to the present invention.

FIG. 2 is a schematic view of a control method according to the present invention. In Figure 1, a motor vehicle is equipped with an internal combustion engine 1 to allow movement of the latter. The internal combustion engine 1 is preferably a Diesel type engine. The internal combustion engine 1 comprises cylinders 2 which are supplied with fuel by respective injectors 3. The latter themselves are supplied with fuel by a common rail 4 which jointly delivers the fuel to the injectors 3. The common rail 4 is type of those commonly called "common rail" according to the English terminology. The common rail 4 is itself supplied with fuel by a high-pressure pump 5 which is interposed on a fuel supply circuit 6 between the common rail 4 and a fuel tank 7. The high-pressure pump 5 is suitable to deliver to the common rail the fuel at an injection pressure Prail which can at most reach a maximum injection pressure Pmax which is of the order of 1500 bars.

The motor vehicle is equipped with a computer 8 which is adapted to implement a method of controlling a fuel supply of the internal combustion engine 1. The computer 8 is for example constitutive of an electronic control unit equipping the motor vehicle. More particularly, the computer is able to calculate a quantity Q of fuel that each injector 3 must inject inside the cylinder 2 to which the injector 3 is assigned. The computer 8 is in relation with the common rail 4 by means of a pressure sensor 9 able to measure and transmit to the computer 8 the Prail injection pressure taken at the common rail 4. The computer 8 is also in connection with the internal combustion engine 1 by means of a torque sensor 10 able to measure and transmit to the computer 8 a motor torque C supplied by the internal combustion engine 1. Thus, in the event of a user's foot lift on an accelerator of the motor vehicle, that is to say in case of a deceleration of the motor vehicle, the engine torque C transmitted to the computer 8 is zero.

According to the present invention, the computer 8 is advantageously in relation with a force sensor 1 1 which is able to deliver to the computer 8 INF information relating to an activation state E of a brake 12 equipping the vehicle automobile. The brake 12 is a control member accessible to a user of the motor vehicle that is intended to slow down or even stop the motor vehicle, particularly from an action on wheels that includes the motor vehicle. The brake 12 is commonly constituted by a pedal operated by means of a foot of the user of the motor vehicle to slow down or even stop the motor vehicle. The brake 12 may consist of an equivalent member without departing from the rule of the present invention. The brake 12 can be activated according to two distinct states: a first state E1 according to which a bearing on the brake is observed to at least slow down the motor vehicle and a second state E2 according to which no bearing on the brake 12 is noted so as not to slow down the motor vehicle through a voluntary action of the user of the motor vehicle. During an occurrence of the first state E1, the force sensor 1 1 transmits to the computer a first information INF1. During an occurrence of the second state E2, the force sensor 1 1 transmits to the computer a second information INF2.

According to the present invention, the control method comprises a calculation step 100 which takes into account the information INF relating to the activation state E of the brake 12 to calculate the quantity Q given of fuel to be delivered by each injectors 3 to the corresponding cylinder, as shown diagrammatically in Figure 2. More particularly, the control method of the present invention is activated if the torque C supplied by the internal combustion engine 1 is zero, that is to say say during a deceleration phase of the motor vehicle.

If the information INF relating to the activation state E consists of the first information INF1, then the quantity Q is calculated as a function of a corrected opening time Te of the injector 4 and the maximum injection pressure Pmax. In other words, if a pressing on the brake 12 is exerted and detected by the sensor of force 1 1, the computer determines the quantity Q of fuel to be injected as a function of the corrected open time Te of the injector 4 and the maximum injection pressure Pmax. The corrected open time Te of the injector 4 is a time determined by the computer 8 which corresponds to a maximum opening time of the injector 3 admissible before a perception by the user of an acceleration.

If the information INF relating to the activation state E consists of the second information INF2, then the quantity Q is calculated as a function of a nominal opening time Tn of the injector 4 and the Prail injection pressure. The nominal opening time Tn of the injector 4 is the running opening time of the injector 4 when the injector 3 receives the fuel at the Prail injection pressure.

The control method also comprises an injection step 101, which follows the calculation step 100, and during which the calculated amount Q of fuel is injected inside each cylinder 2 by each injector 3 correspondent.

Such a control method is capable of being implemented under various deceleration conditions of the motor vehicle and / or in phases where the output torque C of the internal combustion engine 1 is zero, such a reassuring method. at most one operation of the internal combustion engine 1 and avoiding an unpleasant feeling for the user of the motor vehicle, the type of untimely acceleration generated in response to the observed deceleration of the motor vehicle.

Such a control method is implemented by a control device 13 which comprises the computer 8, the pressure sensor 9, the torque sensor 10 and the force sensor 1 1 fitted to the brake 12, such a device 13 control is simple to achieve and install on the motor vehicle.

Claims

1. - A method of controlling a fuel supply system of an internal combustion engine (1), said system comprising at least two injector (3) for injecting a quantity (Q) of fuel into a cylinder, said injectors being fed by a common rail, according to which, in the periods during which the torque request (C) is zero, it is checked whether a request for resetting of the injectors is active, and if this is not the case, it is verified if the quantity of fuel injected is then zero, or in the case of a request for registration of the injectors active, it allows a fuel injection only for a time limit such that the injection associated with the registration does not produce an inadvertent acceleration.

2. Method according to claim 1, characterized in that the periods during which no torque request is made are placed under the control of an information (INF) relating to an activation state E of a brake (12). ).

3. - Method according to claim 2, characterized in that if the torque (C) is zero and if the information (INF) relating to the activation state (E) consists of a first information (INF1) relating to a first state (E1) according to which a pressure on the brake (12) is noted, the quantity (Q) is calculated as a function of a corrected opening time (Te) of the injector (4) and a maximum injection pressure (Pmax).

4. - Method according to claim 2 or claim 3, characterized in that if the pair (C) is zero and if the information (INF) relating to the activation state (E) consists of a second information (INF2) relating to a second state (E2) according to which a support on the brake (12) is not noted, the quantity (Q) is calculated as a function of a nominal opening time (Tn) of the injector (4) and injection pressure (Prail).

5. Control device (13) for implementing a control method according to any one of the preceding claims, characterized in that the control device (13) comprises a computer (8) equipped with a sensor force (1 1) equipping the brake (12). Control device (13) according to claim 5, characterized in that the control device (13) comprises a torque sensor (10) fitted to the internal combustion engine (1).

Control device (13) according to any one of claims 4 and 5, characterized in that the control device (13) comprises a pressure sensor (9) equipping a common rail (4) fitted to the internal combustion engine ( 1).

Motor vehicle equipped with an internal combustion engine (1) provided with a control device (13) according to any one of the claims