FR3027347A1 - METHOD FOR DETERMINING A QUANTITY OF FUEL TO BE INJECTED IN AN INTERNAL COMBUSTION ENGINE - Google Patents

Abstract

A method for determining a quantity of fuel to be injected, via an injector, into a cylinder of an internal combustion engine, this method comprising a step (200) for correcting the quantity of fuel to be injected, this correction being carried out by means of a temperature model (Tinj) of the injector.

Description

FIELD OF THE INVENTION The invention relates to the field of internal combustion engines of motor vehicles and, in particular, to the fuel supply of these engines. The internal combustion engines comprise at least one cylinder defining a combustion chamber for an air / fuel mixture, the combustion chamber being delimited by a cylinder head, at a first end of the cylinder, and by a piston mounted movably in the cylinder, at an end opposite to the cylinder head. The yoke comprises at least two ducts, namely an air intake duct and an exhaust duct, opening into the combustion chamber and each closed by a movable valve between an open position in which the valve is spaced from the cylinder head to allow communication between the conduit and the combustion chamber, and a closed position in which the valve is in contact with the cylinder head and prevents communication between the conduit and the combustion chamber. Finally, the cylinder head comprises an injector through which the fuel is injected directly into the combustion chamber, in the case of a direct injection, or into the air intake duct, in the case of an injection. indirect. The number of injectors in an internal combustion engine is equal to the number of cylinders, or to twice the number of cylinders in the case of an engine having two intake ducts per cylinder and an indirect injection. The fuel is injected, under pressure, into the combustion chambers, the pressurization of the fuel being carried out by a high pressure pump. Injectors used are for example electromagnetic or piezoelectric type and are controlled by a computer that sends an electrical signal to open or close the injector. Thus, the amount of fuel injected depends on the fuel pressure upstream of the injector and the opening time of the injector. The start of an internal combustion engine is a succession of events that starts with the activation of a starter and ends with obtaining a stabilized operating speed of the engine, called idle speed. During startup, there are two main phases, namely a start phase and a post-start phase. During the start phase, of a short duration generally between 500 milliseconds and 10 seconds, there is an increase in the operating speed of the engine from a regime induced by the starter. During the post-departure phase, of about 30 seconds, there is a rapid change in the temperature of the components of the engine including cylinders, valves and fuel injectors. During engine start and especially in the post-departure phase, incomplete combustion of the air / fuel mixture may appear. These incomplete combustions are due to too much fuel injected (rich mixture) or, conversely, too little fuel injected (weak mixture). In the case of incomplete combustion related to a too small amount of fuel injected, there is a rise in engine speed longer compared to normal operation, or, in the worst case, a refusal to start the engine . In the case of incomplete combustion related to too much fuel injected, there is a significant release of smoke output of the engine and fouling or deterioration of the filter elements of the exhaust system of the vehicle, in particular particle filter. These malfunctions of the engine cause immobilization, at least partial, of the vehicle and can cause significant repair costs for its owner. The regulation of the amount of fuel injected is known from EP 2 388 460 describing a motor vehicle comprising a calculator determining a quantity of fuel to be injected into the engine, according to parameters such as the vehicle speed, the power. desired engine and the fuel injection pressure. If this regulation is satisfactory when using the vehicle, it can not be applied to the start of internal combustion engines. A first objective is to provide a method for determining the amount of fuel to be injected when starting the engine. A second objective is to provide a calculator, for internal combustion engine, for determining the amount of fuel to be injected into the engine when it starts. A third objective is to provide an internal combustion engine whose start is not impacted by incomplete combustion. A fourth objective is to propose a motor vehicle comprising an engine meeting the above objectives. For this purpose, it is proposed, in the first place, a method for determining a quantity of fuel to be injected, via an injector, into a cylinder of an internal combustion engine, this method comprising a correction step the amount of fuel to be injected, this correction being performed by means of a temperature model of the injector. The method of determining a quantity of fuel to be injected, via an injector, into a cylinder of an internal combustion engine makes it possible to limit the risk of incomplete combustions when starting the engine. Various additional features may be provided, alone or in combination: - the temperature model of the injector is calculated according to the following formula: Tinj = water + 273 + 9Kn (\ / N x A) where water is the temperature engine water; K is a value obtained according to a speed and a motor torque; n is a specific index for each engine as a function of its displacement; N is the engine speed, and - A is the diameter of the engine cylinder. the method further comprises a step of adding a nominal amount of fuel. It is proposed, secondly, a computer adapted to implement the method of determining a quantity of fuel to be injected, as described above. Advantageously, the computer comprises wired or wireless connection means with an internal combustion engine to receive information from the engine and transmit an injection setpoint to an engine injector. It is proposed, thirdly, an internal combustion engine comprising a fuel injector and a computer, as described above, for creating and transmit an injection instruction to the injector. It is proposed, fourthly, a motor vehicle comprising an internal combustion engine as described above. Other objects and advantages of the invention will become apparent in the light of the description of an embodiment, given hereinafter with reference to the accompanying drawings, in which: FIG. 1 is a perspective view from above of FIG. 'a motor vehicle equipped with an internal combustion engine; Figure 2 is a schematic partial sectional view of a cylinder of the engine of Figure 1; - Figure 3 a curve showing the evolution of the engine speed as a function of time, during the starting phase of the engine; FIG. 4 is an operating diagram of a method for determining the quantity of fuel to be injected into the cylinder of FIG. 2. FIG. 1 shows a motor vehicle 1 comprising an internal combustion engine 2, in this case a 2 diesel engine, but it could be a gasoline engine. The engine 2 comprises an engine block having at least one cylinder 3, a cylinder head 4 covering the engine block and closing the cylinder 3 at an upper end thereof, and a piston 5 movably mounted in the cylinder 3 between a high position, in which the piston 5 is close to the cylinder head 4, and a low position spaced from the high position. As seen in Figure 2, the cylinder 3, the yoke 4 and the piston 5 together define a combustion chamber 6. The yoke 4 comprises two ducts 7, 8 opening into the cylinder 3, namely a duct 7 for admission of air and an exhaust duct 8 after combustion, the ducts 7, 8 comprising, at their junction with the cylinder 3, a valve 9 allowing the communication of a duct 7, 8 with the cylinder 3 or on the contrary the separation between the duct 7, 8 and the cylinder 3. [0031] In addition, the cylinder head 4 comprises, between the two valves 9, a fuel injector 10 for injecting, in the combustion chamber 6, a predetermined quantity of fuel 11. This is called a direct injection in contrast to an indirect injection in which the fuel 11 is injected in the intake duct 7 and mixed with the air before entering the combustion chamber 6. As can be seen in FIG. 2, the engine 2 also comprises a computer 12, by which the quantity of fuel to be injected is determined, and a crankshaft 13 driven in rotation, via rods 14 by the pistons 5. The Movement of the crankshaft 13 is then transmitted to the wheels 15 of the vehicle 1 through different mechanisms. The computer 12 comprises the acquisition, processing and control means required to implement the method for determining a fuel quantity of the invention. The computer 12 is connected to the engine, physically, that is to say by means of cables, or wireless, for example by bluetooth, infrared or wi-fi. The computer 12 then receives information from sensors (not shown) analyzing the operation of the engine 2 and then transmits an instruction 16 to inject a quantity of fuel 11 to the injector 10. The injection instruction 16 is in the form of an electrical signal determining an opening time of the injector 10 [0035] The internal combustion engines 2 comprise several cylinders 3. However, for the sake of clarity and comprehension, the present description and the figures to which it refers relate to a single cylinder, it being understood that all the cylinders of the same engine 2 operate in the same manner. The internal combustion engines 2 operate by succession of cycles, each cycle comprising four phases, namely an intake phase during which the air and the fuel 11 are injected into the combustion chamber 6, a compression phase. and combustion of the air / fuel mixture, a relaxation phase and an exhaust phase. During a hot operation of the engine 2, that is to say when the engine 2 has reached its nominal operating temperature, the amount of fuel 11 injected into the combustion chamber 6, during the phase of operation. admission, depends essentially on an engine speed RM and a torque C requested by the driver, via a vehicle acceleration pedal 1. [0038] The start of an internal combustion engine 2 is a succession of events which starts with the activation of a starter (not shown in the figures) and ends with obtaining a stabilized operating speed of the engine 2, called idle speed. During startup, there are two main phases, namely a start phase 17 and a post-start phase 18. During the initial phase 17, there is an increase in the operating speed of the engine 2, from a regime induced by the starter. During the post-departure phase 18, there is a rapid change in the temperature of the constituent parts of the engine and in particular of the cylinders 3, the valves 9 and the fuel injectors 10. The engine RPM as well as the phases 17, 18 starting and post-departure are shown, as a function of time, on the graph of Figure 3. [0040] When starting the engine 1, and more particularly during the post-departure phase 18, the engine speed RM motor and torque C are substantially constant, only a small variation (due to the stabilization) of the engine speed exists at the beginning of the phase. However, during the starting phases of the engine 2, incomplete combustion in the cylinder 3 may occur. These incomplete combustions are due to a problem of richness of the air / fuel mixture. The richness of an air / fuel mixture is the ratio between the quantity of air and the quantity of fuel 11 injected. It is then said of an air / fuel mixture that it has a high richness when the quantity of fuel 11 injected is too great and, on the contrary, that it has a low richness, when the quantity of fuel 11 injected is too low . In order to determine the quantity of fuel 11 to be injected during the post-departure phase 18, the computer 12 implements a method, illustrated in FIG. 4, comprising a step 100 for calculating the quantity of fuel 11 to inject from engine parameters such as the engine speed RM and engine torque C, and a correction step 200 by means of a temperature model Tinj of the injector 10. Indeed, as we We have seen previously, when the engine 2 starts, the temperature of its constituent elements increases rapidly which causes their expansion. In the case of a direct injection, the expansion of the injector 10 causes its porosity and therefore a higher injection of fuel 11, making the richness of the air / fuel mixture too high. In contrast, in the case of indirect injection, the position of the injector 10 (spaced from the combustion chamber 6) reduces the speed of its rise in temperature and causes a lower fuel injection 11. which makes the richness of the air / fuel mixture too low. The correction step 200 then makes it possible to provide a correction factor taking into account the change in the temperature of the injector 10 so that the quantity of fuel 11 injected is in accordance with the requirement of the engine 2. [1] 0047] For this, the model of temperature Tinj of the injector is calculated according to the following formula: Ijnj Tea, + 273 + 9Kn (I \ 'N / <A) where -' water is the temperature of the water of the motor 2; K is a value obtained as a function of the engine speed RM and the engine torque C; n is a specific index for each engine 2 as a function of its displacement; - N is the engine speed RM, and - A is the diameter of the cylinder 3 of the engine 2. [0048] The method further comprises a step 300 of adding a nominal Onomi quantity of fuel 11 to be injected. The nominal OnOilli quantity of fuel 11 is predetermined by engine manufacturers and remains constant during the use of the engine 2. [0049] Thus, the instruction 16 for injecting a quantity of fuel 11 into the cylinder 3 of the engine 2 is the sum of the nominal Onorni amount of fuel 11 and the correction factor obtained in the correction step 200. The process that has just been proposed has the following advantages. First, it avoids incomplete combustion when starting the engine 2. Indeed, taking into account the temperature of the injector 10 when starting the engine 2 allows to control more precisely the amount fuel 11 injected into the combustion chamber 6. Thus, despite the rapid evolution of the temperature of the engine 2 and its component parts, the computer 12 corrects the nominal Onomi quantity of fuel 11 to be injected thanks to the temperature model Tin; of the injector 10. For example, if the injector 10 is cold and slightly dilated, the correction causes a sharp increase in the amount of fuel 11 to be injected with respect to the nominal amount Onomi, whereas if the Injector 10 is hot, the correction causes a small increase in fuel 11 to inject compared to the nominal amount Onomi. The temperature of the injector 10 is particularly related to the surrounding atmospheric conditions of the vehicle 1 automobile, and more particularly at room temperature. Thus, at a low ambient temperature, that is to say a temperature close to 0 ° C. or negative, the evolution of the temperature of the injector 10 will be lower than for a high ambient temperature; that is greater than or equal to 20 ° C. Then, the life of the engine 2 and its components, as well as various elements of the vehicle 1, such as a particulate filter, for example, is increased. Indeed, the reduction of the risk of incomplete combustion avoids excessive fatigue of the starter of the vehicle 1 due to forced use, or destruction of the particle filter linked to the fuel injection 11, unburned from the chamber 6 combustion to the particulate filter.

Claims (7)

REVENDICATIONS1. A method of determining a quantity of fuel (11) to be injected, via an injector (10), into a cylinder (3) of an internal combustion engine (2), said method being characterized in that it comprises a step (200) for correcting the amount of fuel (11) to be injected, this correction being performed by means of a temperature model (Ti nj) of the injector (10). 2. Method according to the preceding claim, characterized in that the temperature model (Tinj) of the injector (10) is calculated according to the following formula: Ijnj Tea, + 273 + 9Kn (I \ 'N / <A) where water is the temperature of the engine water; K is a value obtained as a function of a speed (RM) and a torque (C) motor; n is a specific index for each engine (2) as a function of its displacement; N is the engine speed (RM), and A is the diameter of the cylinder (3) of the engine (2). 3. Method according to any one of the preceding claims, characterized in that it further comprises a step (300) of adding a nominal amount (Onomi) of fuel (11). 4. Calculator (12) adapted to implement the method of determining a quantity of fuel (11) to be injected, according to any one of the preceding claims. 5. Calculator (12) according to the preceding claim, characterized in that it comprises wired or wireless connection means with an internal combustion engine (2) for receiving information from the engine and transmit a set (16) d injection to an injector (10) of the engine (2). 6. Internal combustion engine (2) comprising an injector (10) of fuel (11) and a calculator (12) according to claim 4 or claim 5 for creating and transmitting an instruction (16) injection to the injector (10). 7. Vehicle (1) automobile comprising an internal combustion engine (2) according to the preceding claim. 10